Monosaccharide transport by Eimeria tenella sporozoites

Eimeria tenella sporozoites were incubated in the presence of 3 different [14C]-labeled sugars; D-glucose, 2-deoxy-D-glucose and 3-O-methyl-D-glucose. The initial velocity, Vi, of uptake of D-glucose and 2-deoxy-D-glucose was similar, 41 micrograms/10(10) sporozoites/min and 46 micrograms/10(10) sporozoites/min, respectively; whereas that for 3-O-methyl-D-glucose was significantly lower, 17 micrograms/10(10) sporozoites/min. Initial velocity studies also revealed that glucose uptake was a saturable event, with an apparent KT of 20 mM and an apparent Vmax of 312 micrograms/10(10) sporozoites/min. Uptake was unaffected by exogenous sodium levels or the presence of ouabain. However, 0.1 mM phloretin significantly inhibited glucose uptake. Thus, it would appear that E. tenella sporozoites possess a Na-independent, phloretin-sensitive, carrier-mediated monosaccharide-transport system.     

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.     

Eimeria tenella: immunogenicity of arrested sporozoites in chickens

Groups of chickens were medicated with the anticoccidial drug, decoquinate, and starting 1 day after this medication they were given daily inoculations of either 1 X 10(4) (Experiment 1) or 1 X 10(5) (Experiment 2) oocysts of a decoquinate-sensitive strain of Eimeria tenella. This assured the presence of large numbers of drug-inhibited sporozoites in the cecal tissues. The immunity arising from the presence of these inhibited sporozoites was assessed by challenging the medicated chickens with a 2.5 X 10(5) oocysts of a decoquinate-resistant strain of E. tenella. The response to challenge was assessed by weight gain, the severity of cecal lesions, hematocrits, and cecal oocyst numbers. The inhibited sporozoites promoted little (if any) immunity judged by clinical signs of disease. However, judged by body weight changes after challenge, the presence of inhibited sporozoites provided substantial protection against the body-weight-depressing effects of the challenge dose. These findings emphasize the importance of stage-specific antigen expression in Eimeria spp. infections and support the notion that immunogenicity is associated with tropic stages of the parasite.     

Capping of immune complexes by sporozoites of Eimeria tenella

Sporozoites of Eimeria tenella were incubated for 10, 20, or 30 min with parasite-specific monoclonal IgG antibody 3D3II from mice and then rinsed in a Tris-buffered glucose saline solution (TBGS). Some sporozoites were then incubated for 10, 20, or 30 min with ferritin- or colloidal gold-conjugated goat anti-mouse IgG antibody and then fixed in 2.5% glutaraldehyde and prepared for transmission (TEM) or scanning (SEM) electron microscopy. Other sporozoites that had been previously exposed to monoclonal antibody were prefixed with 0.25% glutaraldehyde, incubated with ferritin- or colloidal gold-conjugated anti-mouse IgG antibody and then fixed and prepared for TEM or SEM. Control preparations consisted of sporozoites exposed only to TBGS, monoclonal antibody 3D3II or to ferritin- or colloidal gold-conjugated anti-mouse IgG antibody. Capping of immune complexes occurred only on the surface of those sporozoites exposed to monoclonal antibody 3D3II followed by ferritin- or gold-conjugated antibody. Immune complexes moved laterally and posteriorly on the outer surface of the parasite plasma membrane to form a cap at the posterior end of the sporozoite. Capping did not occur in TBGS controls nor in sporozoites treated with monoclonal antibody 3D3II and prefixed in 0.25% glutaraldehyde before exposure to ferritin- or gold-conjugated antibody. Thus, capping of surface antigens did not occur in the presence of monoclonal 3D3II antibody only, whereas specimens exposed to both monoclonal and ferritin- or colloidal gold-conjugated antibodies were able to cap immune complexes.     

In vitro activity of the human neutrophil cathepsin G on Eimeria tenella sporozoites

The role of human neutrophil cathepsin G (Cat G) on Eimeria tenella sporozoites was studied in vitro. Sporozoites were incubated for 2 hr at 37 C in PO4 buffer, 0.9% NaCl (PBS), pH 7.6 in the presence of Cat G (50 micrograms/ml), diisopropyl fluorophosphate-inhibited Cat G (DFP-Cat G) (50 micrograms/ml) or PBS alone, prior to being inoculated into embryonated eggs. As judged by oocyst production on day 7 postinoculation, embryo mortality and the hemorrhage scores, both Cat G and DFP-Cat G demonstrated anticoccidial activity; greater activity was obtained with the DFP-Cat G. Sporozoites were exposed also to increasing concentrations of native and trypsin-digested DFP-Cat G (0-100 micrograms/ml) under the same conditions. Significant protection (37% and 49% for native and digested DFP-Cat G, respectively) was obtained with a low concentration (5 mu/ml), and higher concentrations resulted in 70% and 84% protection, respectively. The primary bactericidal domain of Cat G, the HPQYNQR peptide, at 3 concentrations (25, 50, and 100 micrograms/ml), reduced the oocyst production by 46%, 16%, and 15%, respectively. The anticoccidial activity of Cat G may involve a peptide fragment different from the antimicrobial domain of the enzyme.     

Eimeria tenella: accumulation and retention of anticoccidial ionophores by extracellular sporozoites

Extracellular sporozoites of Eimeria tenella were incubated at either 25 or 40 C in the presence of ¹⁴C-lasalocid or ¹⁴C-narasin, both anticoccidial ionophores. Liquid scintillation analysis shows that both ionophores are accumulated by the sporozoites outside their host cell. The relative degree of retention was significantly different for the two incubation temperatures and the concentration of lasalocid retained was consistently greater than that of narasin.     

The use of sodium taurodeoxycholate for excystation of Eimeria tenella sporozoites

As an in vitro excystor, sodium taurodeoxycholate (TDC) released 80--90% Eimeria tenella sporozites, in contrast to 0--15% excystation by six other bile salts or bile extracts, and pooled chicken bile in 90 min at 37 C with continuous agitation. Pooled chicken bile required 4 to 4 1/2 hr to excyst similar percentages of sporozoites. Prolonged incubation with other bile salts and bile extracts excysted most sporozoites, but killed them. When the incubation temperature was raised to 44 C, TDC excysted 100% of the sporozoites in 60 min. In all other bile salts or bile extracts, the percentage of excystation increased greatly at 44 C, but none equalled that of TDC. The molecular similarity of TDC to a naturally occurring bile salt of chickens is presented as an explanation for the superior performance of TDC as an excystor. Data are examined to minimize the possibility that excysting activity of TDC can be attributed to other bile salts present at impurities.     

Penetration of Eimeria tenella sporozoites under different oxygen concentrations in vitro.

Sporozoites of Eimeria tenella (Wisconsin strain) were inoculated onto monolayers of normal chicken kidney fibroblasts and cultured in RPMI-1640 supplemented with 5% fetal bovine serum, sodium bicarbonate, and gentamicin under either aerobic, 5% CO2/95% air, or anaerobic conditions. Penetration of fibroblasts by sporozoites under CO2 or anaerobic conditions at 2 and 24 hr postinoculation was 3-4 times greater than that in the aerobic atmosphere. Effect of reduced oxygen concentrations, i.e., 20.0, 12.5, and 5.0% oxygen, was also investigated in an N2-O2-CO2 incubator. Under 5.0 and 12.5% oxygen at 2 and 24 hr postinoculation, the number of sporozoites that penetrated was about 4 and 2 times greater, respectively, than under 20.0% O2. These results indicate that lower oxygen concentrations provide for greater penetration by E. tenella sporozoites in cultured cells.     

Influence of monensin on cation influx and glycolysis of Eimeria tenella sporozoites in vitro

Extracellular Eimeria tenella sporozoites exposed to 1.0 microgram/ml monensin at 40 C had an accelerated rate of sodium influx as well as an increased rubidium uptake that was inhibited by the cardiac glycoside, ouabain. These results suggested the presence of a functional (Na+-K+)-ATPase and its stimulation by monensin. Under the same conditions, sporozoite ATP concentrations declined, lactate production increased and the rate of amylopectin utilization was enhanced. Exposure to monensin also appeared to stimulate the rate of sporozoite glycolysis. The results of this study demonstrated that the cidal effect of monensin on extracellular sporozoites was caused by the capability of the ionophore to act as a transmembrane sodium carrier.     

Expression of flotillin-1 on Eimeria tenella sporozoites and its role in host cell invasion

Lipid rafts are detergent-resistant, liquid-ordered microdomains in plasma membranes that are enriched in cholesterol and sphingolipids and involved in intracellular signal transduction, membrane trafficking, and molecular sorting. In this study, we investigated the possibility that lipid rafts on Eimeria tenella sporozoites may act as platforms for host cell invasion. Flotillin-1, a resident protein of lipid rafts, was identified on E. tenella sporozoites and was prominently expressed at the apex of the cells, a region mediating host cell invasion. Pretreatment of sporozoites with antibody against flotillin-1 blocked parasite invasion. Furthermore, the anticoccidial drug, monensin, disrupted the localization of flotillin-1 within raft structures resulting in loss of invasion. We conclude that Eimeria sporozoites utilize lipid rafts containing flotillin-1 for internalization into host cells.