The entry of sporozoites of Theileria parva into bovine lymphocytes in vitro. Immunoelectron microscopic observations

In an electron microscopic investigation of the entry of sporozoites of Theileria parva into bovine lymphocytes, the fate of the surface coat of the parasite was traced by immunocytochemical methods. A monoclonal antibody (MAbD1) raised in mice and directed against a surface antigen of sporozoites, was applied to ultrathin frozen sections of bovine lymphocytes infected in vitro. Sites of binding of MAbD1 were localized using a protein A-colloidal gold conjugate as an electron-dense label. The surface of all free sporozoites was labelled. Sporozoites in the process of entering were labelled only on that portion of the membrane not yet tightly bound to the lymphocyte membrane. No label was detected on sporozoites that had completed entry. After fixation with formaldehyde, but not with glutaraldehyde, local areas of labelling were found on lymphocytes in contact with sporozoites and on cells already invaded. The sporozoite organelles, called micronemes, occasionally appeared to contain labelled antigen. No label was found on sporozoites or lymphocytes in control preparations previously exposed to non-specific antibody or treated with protein A-colloidal gold alone. The findings support the conclusion that the sporozoite surface coat, containing the antigen recognized by MAbD1, is shed as the sporozoite enters the host cell.     

Plasmodium malariae: distribution of circumsporozoite protein in midgut oocysts and salivary gland sporozoites

The distribution of the circumsporozoite protein within developing Plasmodium malariae oocysts and salivary gland sporozoites was examined by immunoelectron microscopy using protein A-gold and a monoclonal antibody specific for the CS protein of P. malariae. Gold particles were found along the capsule of immature oocysts but rarely within the cytoplasm. Gold label was detected on the inner surface of peripheral vacuoles during oocyst maturation and the plasma membrane of the sporoblast. Salivary gland sporozoites and budding sporozoites in mature oocysts were labeled uniformly on the outer surface of their plasma membranes. The surface of sporozoites that ruptured into midgut epithelial cells were entirely covered with gold particles. No label was seen on the surface of sporozoites which ruptured into the midgut lumen. In addition, a rabbit polyclonal antibody against repeat a region of P. brasilianum CS protein reacted with P. malariae sporozoites.     

Interactions of Plasmodium berghei sporozoites and murine Kupffer cells in vitro

Malaria sporozoites must leave the bloodstream and cross a layer of sinusoidal lining cells in order to infect hepatocytes and undergo exoerythrocytic schizogony. To determine whether Kupffer cells (KC) derived from this layer interact with sporozoites, murine KC were isolated from perfused livers of BALB/cJ mice and incubated in vitro with Plasmodium berghei sporozoites. Isolated KC had characteristic macrophage surface Ag and were phagocytic, ingesting both latex particles and Leishmania major amastigotes. In the absence of immune serum, sporozoites associated with fewer than 10% of these KC. By 30 min, 10% of the cell-associated sporozoites were completely ingested, 30% were in the process of being ingested, and 60% were attached to the surface of the cells. Opsonization of sporozoites with monoclonal or polyclonal antibodies directed against P. berghei circumsporozoite protein markedly enhanced sporozoite association with KC. Up to 40% of cells exposed to opsonized sporozoites had parasites inside or attached to their surfaces. Sporozoites attached to or ingested by KC were uniformly destroyed within 240 min in all cultures; there was no evidence of conversion of sporozoites to the exoerythrocytic stage within KC by light microscopy, and there was no evidence of residual sporozoites, either inside or outside of cells, by either light or electron microscopy. These data suggest that under nonimmune conditions, KC play a minor role in resistance to infection by malaria sporozoites. However, when sporozoites are opsonized by circumsporozoite antibodies, phagocytosis by KC may be an important immune mechanism that prevents parasitization of hepatocytes.     

Exit of Plasmodium sporozoites from oocysts is an active process that involves the circumsporozoite protein

Plasmodium sporozoites develop within oocysts residing in the mosquito midgut. Mature sporozoites exit the oocysts, enter the hemolymph, and invade the salivary glands. The circumsporozoite (CS) protein is the major surface protein of salivary gland and oocyst sporozoites. It is also found on the oocyst plasma membrane and on the inner surface of the oocyst capsule. CS protein contains a conserved motif of positively charged amino acids: region II-plus, which has been implicated in the initial stages of sporozoite invasion of hepatocytes. We investigated the function of region II-plus by generating mutant parasites in which the region had been substituted with alanines. Mutant parasites produced normal numbers of sporozoites in the oocysts, but the sporozoites were unable to exit the oocysts. In in vitro as well, there was a profound delay, upon trypsin treatment, in the release of mutant sporozoites from oocysts. We conclude that the exit of sporozoites from oocysts is an active process that involves the region II-plus of CS protein. In addition, the mutant sporozoites were not infective to young rats. These findings provide a new target for developing reagents that interfere with the transmission of malaria.     

Separation of enzymes from microorganism crude extracts by free-flow zone electrophoresis

Continuous, single-step, state-of-the-art preparative separations of enzymes from microorganism crude extracts by free-flow zone electrophoresis are presented. In the first example, the enzymes formate dehydrogenase, formaldehyde dehydrogenase, and methanol oxidase were continuously separated from Candida boidinii crude extract. Yields of 85% to 95% and purification factors between 3 and 7 were obtained along with a simultaneous separation of the finer cell debris from the enzymes. Using multiple injections of sample, a throughput of 46.2 mg protein/h was recorded. In the second example, a fivefold purification of beta-galactosidase from Escherichia coli was achieved along with complete, simultaneous cell debris separation from the enzyme. The yield of the enzyme was greater than 90%. The preparative free-flow zone electrophoresis experiments were run continuously for a period of 12 h and the separations were found to be stable; i.e., the enzymes and the cell debris eluted at their respective fraction numbers during the entire period. In both examples, choice of the type of buffer played a critical role and had to be investigated and optimized experimentally. Scale-up aspects of the separations are also discussed. Recently, by comparison of free-flow zone electrophoresis with ion-exchange chromatography, we have presented evidence that free-flow electrophoresis separations are governed by net surface charge (S. Nath et al., Biotechnol. Bioeng. 1993, 42: 829-835). Here, we offer further confirmation of this evidence by comparison of preparative free-flow zone electrophoresis experiments at various pHs on a mixture of two model proteins with analytical electrophoretic titration curves of the proteins. We are thus in a position to predict separations in free-flow zone electrophoresis. (c) 1996 John Wiley & Sons, Inc.     

Effects of cationized ferritin and neuraminidase on invasion of cultured cells by Eimeria meleagrimitis sporozoites

Primary turkey kidney cells and Eimeria meleagrimitis sporozoites were treated with cationized ferritin (CF) or neuraminidase ( NANase ), and the effects on the invasion of the cells by the sporozoites were measured. Cultures of host cells pretreated with either compound contained significantly fewer intracellular sporozoites than did control cultures. There was little additive effect if cultures were first treated with NANase and then with CF. In contrast, pretreatment of sporozoites with CF or low concentrations of NANase had no effect on invasion. The inhibition of invasion was apparently due to an interaction between treatment substances and host cell surface rather than to direct effect on the sporozoites. The CF bound to the randomly distributed anionic sites on the surfaces of both host cells and sporozoites and then rapidly aggregated. Sporozoites, probably in the process of invading cells, were invariably found with the conoid in close association with aggregates of CF on the host cell membrane. The CF on the sporozoites was apparently shed before or during invasion because all intracellular sporozoites were completely devoid of the label.     

Molecular interactions of cultured turkey kidney cells with specific antigens of Eimeria adenoeides sporozoites

Earlier studies suggested that specific communication between the parasite and the host cell may play a role in cellular invasion by sporozoites of species of avian Eimeria. In this study, quantification of cellular invasion and modified Western blot analysis were used to explore the possibility that parasite receptors for interaction with the host cell might be involved in the sporozoite-host cell communication. Invasion in cultured cells treated with a homogenate of Eimeria adenoeides sporozoites was approximately 50% lower than that in untreated cultures. When the sporozoite homogenate was solubilized in sodium dodecyl sulfate and electrophoretically separated, components of the cultured host cells bound consistently to sporozoite bands having Mr of 23 and 40 kDa. Biotinylation of intact sporozoites revealed at least 14 biotin-labeled bands, including bands at 23 and 40 kDa, that were considered to be surface molecules. If the sporozoites were incubated in trypsin after they were biotinylated, only two biotinylated bands at 18 and 23 kDa remained; the 40-kDa biotinylated band was not detected. Despite the removal of the majority of the surface molecules, the cell homogenate still bound to the trypsin-treated sporozoites; the intensity of the label was similar to that resulting from the binding of cell homogenate to untreated sporozoites. The data show specific interactions between 23- and 40-kDa sporozoite bands and host cell components, and provide evidence that the 23-kDa molecule may be located on the sporozoite surface and the 40-kDa molecule located intracellularly.     

Sporozoites of Rodent and Simian Malaria, Purified by Anion Exchangers, Retain their Immunogenicity and Infectivity

SYNOPSIS. Sporozoites of rodent malaria, Plasmodium berghei , and simian malaria, Plasmodium knowlesi and Plasmodium cynomolgi , were partially separated from mosquito debris and microbial contaminants by passage of Anopheles material through a DEAE-cellulcse column. In addition to eliminating most of the contaminants (80–90%), this simple technic has made it possible to recover rapidly large numbers of viable sporozoites (55–75% yield), which have retained their infectivity, immunogenicity, and capacity to react with known antisera. Mice injected with varying doses of column-purified sporozoites (CS) of P. berghei produced infections which paralleled those seen in the controls. Total protection against challenge with a potentially lethal dose of viable sporozoites was acquired by mice inoculated twice with irradiated CS of P. berghei. CS of P. berghei and P. cynomolgi gave positive circumsporozoite precipitation (CSP) reactions, upon inoculation with the respective immune sera. The preservation of the surface antigens of CS was documented by immunofluorescence.
It was shown that differences in elution behavior exist among sporozoites of certain species of Plasmodium as well as among sporozoites of the same species derived from different organs of the mosquito. These results may be attributed to differences in the surface charge of the sporozoites or conditions in sample media.
Purified sporozoites obtained by the method described in this report provide an adequate source of parasites for a variety of in vitro studies.     

Effects of Cationized Ferritin and Neuraminidase on Invasion of Cultured Cells by Eimeria meleagrimitis Sporozoites

Primary turkey kidney cells and Eimeria meleagrimitis sporozoites were treated with cationized ferritin (CF) or neuraminidase (NANase), and the effects on the invasion of the cells by the sporozoites were measured. Cultures of host cells pretreated with either compound contained significantly fewer intracellular sporozoites than did control cultures. There was little additive effect if cultures were first treated with NANase and then with CF. In contrast, pretreatment of sporozoites with CF or low concentrations of NANase had no effect on invasion. The inhibition of invasion was apparently due to an interaction between treatment substances and host cell surface rather than to direct effect on the sporozoites. The CF bound to the randomly distributed anionic sites on the surfaces of both host cells and sporozoites and then rapidly aggregated. Sporozoites, probably in the process of invading cells, were invariably found with the conoid in close association with aggregates of CF on the host cell membrane. The CF on the sporozoites was apparently shed before or during invasion because all intracellular sporozoites were completely devoid of the label.     

Ultrastructural Observations on the Infection of Rat Liver by Plasmodium berghei Sporozoites In Vivo1

The invasion of liver parenchymal cells by sporozoites of Plasmodium berghei Vincke & Lips, 1948, was studied in vivo using transmission electron microscopy. Livers of Brown Norway rats were examined 30 and 60 min after intraportal injection of 15 million sporozoites each. Sporozoites found after incorporation into vacuoles in hepatocytes were often located near a bile canaliculus at the lateral cell surface, surrounded by hepatocyte lysosomal structures; however, degradation of sporozoites caused by lysosomal digestion inside hepatocytes was never observed. Due to the crescent shape of sporozoites, serial sections were necessary to demonstrate the actual process of invasion of the hepatocyte. The hepatocyte's plasmalemma appeared to invaginate due to the sporozoite's action, thereby creating a parasitophorous vacuole. It was suggested that the sporozoite actively penetrated the hepatocyte; however, no visible depletion of rhoptries and micronemes was observed.     

Ultrastructural observations on the infection of rat liver by Plasmodium berghei sporozoites in vivo

The invasion of liver parenchymal cells by sporozoites of Plasmodium berghei Vincke & Lips, 1948, was studied in vivo using transmission electron microscopy. Livers of Brown Norway rats were examined 30 and 60 min after intraportal injection of 15 million sporozoites each. Sporozoites found after incorporation into vacuoles in hepatocytes were often located near a bile canaliculus at the lateral cell surface, surrounded by hepatocyte lysosomal structures; however, degradation of sporozoites caused by lysosomal digestion inside hepatocytes was never observed. Due to the crescent shape of sporozoites, serial sections were necessary to demonstrate the actual process of invasion of the hepatocyte. The hepatocyte's plasmalemma appeared to invaginate due to the sporozoite's action, thereby creating a parasitophorous vacuole. It was suggested that the sporozoite actively penetrated the hepatocyte; however, no visible depletion of rhoptries and micronemes was observed.     

Conserved group-specific epitopes of the circumsporozoite proteins revealed by antibodies to synthetic peptides

The immunogenic properties of sporozoites are associated mainly with the circumsporozoite (CS) protein that covers the surface of mature sporozoites. This stage-specific protein has an immunodominant region with repetitive epitopes. Rabbits that are repeatedly immunized with sporozoites of Plasmodium knowlesi, a monkey malaria parasite, also recognize two synthetic peptides (N2 and C2) representing other polar domains of the CS protein. We show in this report that antibodies to the N2 and C2 synthetic peptides react not only with P. knowlesi but also with conserved regions of the surface membrane of other human, monkey, and rodent (but not avian) malaria sporozoites. Moreover, antibodies to N2 partially neutralize the infectivity of sporozoites of P. berghei, a rodent malaria parasite. In contrast, antibodies to synthetic peptides representing the repetitive epitope of P. knowlesi were strictly species specific.     

Ultrastructural localization of antigenic sites on sporozoites, sporocysts, and oocysts of Eimeria acervulina and Eimeria tenella by monoclonal IgG and IgM antibodies

Immunoelectron microscopy was used to study the localization of monoclonal IgG (13.9 and 15.84) and IgM (10.84) antibodies generated against Eimeria tenella sporozoites on sporozoites, sporocysts, and oocysts of Eimeria acervulina and E. tenella. A uniform layer of ferritin was present on sporozoites of E. tenella fixed chemically before the addition of 10.84, 13.90, or 15.84 (called prefixed), whereas postfixed (fixed chemically after exposure to monoclonal antibody) sporozoites lacked ferritin, indicating that the latter had capped immune complexes. Patches of ferritin were present on prefixed and postfixed sporozoites of E. acervulina exposed to 15.84, indicating that immune complexes containing 15.84 were not capped. Sporocysts of E. tenella exposed to 10.84 had a uniform layer of ferritin on their outer surface; ferritin was localized in patches on those exposed to 13.90 or 15.84. In E. acervulina sporocysts exposed to 15.84, ferritin was widely scattered on the outer surface but formed a uniform layer on the inner surface of the sporocyst wall. Patches of ferritin occurred on the inner layer of the oocyst walls of E. tenella and E. acervulina exposed to 10.84, 13.90, or 15.84. These findings indicate the shared antigen detected by 15.84 differed in relative amount, spatial distribution, and structural location in sporozoites and sporocysts of E. acervulina and E. tenella.     

Identification of antigens of Sarcocystis cruzi sporozoites, merozoites, and bradyzoites with monoclonal antibodies

Sporozoites and culture-derived merozoites of Sarcocystis cruzi were used to elicit monoclonal antibodies (MAb's) in mice. Some of these antibodies reacted with the surface of live sporozoites and merozoites as determined by immunofluorescence. An array of similar antigens was identified in Western blots of sporozoites by both anti-merozoite MAb's and an anti-sporozoite MAb. At least 1 antigen in blots of bradyzoites was identified by anti-merozoite MAb's and a cluster of antigens was identified by an anti-sporozoite antibody. These results indicate that several surface epitopes of sporozoites and merozoites are shared with molecules of bradyzoites and that antigen patterns of molecules bearing these epitopes in 3 stages of Sarcocystis may be either distinct or similar.     

Sporozoites of rodent and simian malaria, purified by anion exchangers, retain their immunogenicity and infectivity.

Sporozoites of rodent malaria, Plasmodium berghei, and simian malaria, Plasmodium knowlesi and Plasmodium cynomolgi, were partially separated from mosquito debris and microbial contaminants by passage of Anopheles material through a DEAE-cellulose column. In addition to eliminating most of the contaminants (80-90%), this simple technic has made it possible to recover rapidly large numbers of viable sporozoites (55-75% yield), which have retained their infectivity, immunogenicity, and capacity to react with known antisera. Mice injected with varying doses of column-purified sporozoites (CS) of P. berghei produced infections which paralleled those seen in the controls. Total protection against challenge with a potentially lethal dose of viable sporozoites was acquired by mice inoculated twice with irradiated CS of P. berghei CS of P. berghei and P. cynomolgi gave positive circumsporozoite precipitation (CSP) reactions, upon inoculation with the respective immune sera. The preservation of the surface antigens of CS was documented by immunofluorescence. It was shown that differences in elution behavior exist among sporozoites of certain species of Plasmodium as well as among sporozoiters of the same species derived from different organs of the mosquito. These results may be attributed to differences in the surface charge of the sporozoites or conditions in sample media. Purified sporozoites obtained by the method described in this report provide an adequate source of parasites for a variety of in vitro studies.     

Effects of Intestinal Contents from Normal and Immunized Mice on Sporozoites of Eimeria falciformis1

The interaction of Eimeria falciformis sporozoites with the intestinal epithelium and with the intestinal contents from the cecum and colon of normal and specifically immunized mice was studied by light (LM) and scanning electron (SEM) microscopy. Fecal (FM) and enterocyte-associated (EAM) mucus were removed from the cecum and colon of normal mice and mice that had been immunized 1, 6, 12, or 20 days earlier with a series of oral inoculations of E. falciformis oocysts. Sporozoite-specific IgA, but neither IgM nor IgG, was detected by the immunofluorescent antibody test in FM and EAM from immunized mice. No sporozoite-specific immunoglobulin was detected in normal mice. When examined by LM, sporozoites exposed to all FM and EAM preparations exhibited greater motility and excystation from sporocysts. At 4 h after incubation in FM or EAM from normal or immune mice, about 10% of the sporozoites appeared damaged, being non-motile and non-refractile. Immune FM and EAM caused agglutination of sporozoites and sporocysts and oocyst walls of E. falciformis. but did not agglutinate those of E. ferrisi. Scanning electron microscopy of in vitro interactions between E. falciformis sporozoites and intestinal contents revealed that sporozoites exposed to immune EAM were coated with particulate material whereas those exposed to normal EAM were relatively clean. Sporozoites exposed to immune FM were usually embedded within the mucus whereas those exposed to normal FM were situated on top of the mucus. No significant differences occurred between the length/width (L/W) ratios of sporozoites incubated in normal FM and EAM or in PBS. Sporozoites exposed to immune FM had significantly greater L/W ratios than those exposed to normal FM whereas those exposed to immune EAM had significantly shorter L/W ratios than ones exposed to normal EAM. Few of the sporozoites observed on the luminal surface of the colon and cecum of normal mice were covered by mucus and none was altered in shape or showed pellicular damage. Only a few sporozoites were observed on the luminal surface of the colon and cecum of immunized mice. Most of these were covered by mucus and some exhibited pellicular alterations.     

Flotillin-1 localization on sporozoites oF Eimeria tenella

In an attempt to identify parasite surface components involved in the interaction with the host cell, the present research focuses on the rafts of Eimeria tenella that might be involved in the host cell invasion process. To that end, this study was undertaken to investigate the expression of flotillin-1, which is an important component and marker of lipid rafts at the plasma membrane of sporozoites of E. tenella. The expression of this plasma membrane protein was identified by an antibody that specifically reacts with flotillin- and was studied by electron microscopy. Flotillin-1 was found to occur in patches on the surface of E. tenella sporozoites. Immunoblot analysis of the total proteins of the sporozoites showed only 1 band of approximately 48 kDa. This indicates that the antibody exclusively recognized the molecules of flotillin-1 expressed on the surface of E. tenella sporozoites. The presence of flotillin-1 on the cellular membrane of sporozoites predominantly at the apical tip suggests that flotillin-1 belongs to the invasion machinery of E. tenella.     

Surface Changes Induced by Immune Serum on Eimeria tenella Sporozoites and Merozoites

ABSTRACT. The surface of merozoites and sporozoites of Eimeria tenella was affected by incubation with E. tenella -immune chicken serum (ICS). Normal chicken serum (NCS) and heat-inactivated ICS had no effect on the pellicular surface of either developmental stage. Sporozoites formed surface bulges or swellings after 10 min of incubation with ICS, and by 15 min postincubation, the morphology of the sporozoites was distorted by a surface coating of fibrinous material. Merozoites exposed to ICS were similarly coated, but surface swelling was not as severe. The coating formed rapidly and was seen as early as 5 min postincubation. Sporozoites incubated with heat-inactivated ICS supplemented with normal chicken serum were coated with a fibrinous material and in some cases lysed. These data indicated that complement must be present for the surface interaction to occur.     

Plasmodium berghei: immunologically active proteins on the sporozoite surface

With an improved separation procedure for Plasmodium berghei sporozoites, up to 2000 mosquitoes can be processed in 3 to 4 hr. The method is based on density gradient centrifugation in Percoll. The small amount of contaminating microbial material did not noticeably interfere with the radiolabeling of surface proteins of the purified sporozoites. Two labeled proteins, with molecular weights of about 110,000 and 53,000 daltons, respectively, were identified using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both proteins reacted specifically with antibodies against salivary gland sporozoites raised in rabbits and in rats. These two proteins were also present on the surface of “immature” sporozoites isolated from mosquitoes 12 days after the infective blood meal. None of these proteins, apparently, is involved in the cross-reactivity of sporogonic stages with blood stages.     

Plasmodium berghei: sporozoites are sensitive to human serum but not susceptible host serum.

Human complement was activated by rodent malaria, Plasmodium berghei, sporozoites through the alternative pathway, as revealed by C3 deposition on sporozoites using the fluorescent antibody technique. Sporozoites exposed to fresh human serum decreased in infectivity to HepG2 cells, but those exposed to heated or C3-deficient human serum showed normal infectivity to HepG2 cells. In contrast, C3 deposition was not observed on the sporozoites treated with mouse or rat serum even in the presence of specific polyclonal anti-sporozoite antibody. However, following treatment with trypsin (250 micrograms/ml), 81% of salivary gland sporozoites and 49% of oocyst sporozoites became reactive with mouse serum, and reactive sporozoites deposited mouse C3 on their surface in the presence of 30 mM EGTA and 1 mM Mg2+ without antibody. Concomitantly some sporozoites lost reactivity to anti-circumsporozoite protein monoclonal antibody. These results suggest that P. berghei sporozoites possibly express surface molecules that regulate the complement activation pathway of susceptible hosts but not of nonhosts, and that the putative structures consist of protease-sensitive molecule(s) which are closely associated with the circumsporozoite protein.