Immunochemical Characterization of Setaria cervi Microfilarial Antigens Using Novel Antibodies

Background:Filariasis affects millions of people in tropical and subtropical regions of the world and is caused by nematode roundworm. In order to develop a vaccine and specific diagnostic tests, it is important to characterize different stages of the filarial worms. Microfilariae (Mf) stage of the roundworm is found in host’s blood or lymph vessels and can be important not only for developing better immunodiagnostics but also for understanding immune recognition and its relevance to immunepathogenesis and protective immunity.Objective:The present study aimed to immunocharacterize Mf and adult worm antigens that could be helpful in future diagnostic tests.Method:Four different immune sera against Setaria cervi intact live, intact live with adjuvant, intact glutaraldehyde fixed with adjuvant and total somatic Mf were prepared and used for the immunocharacterization of Mf antigens.Results:Our study results suggest that compared to fixed intact Mf, live intact Mf are more immunogenic, as the immune sera generated against intact live Mf showed high ELISA reactivity with Setaria cervi Mf and adult worm antigens. All the four immune sera IgG fractions had surface specificity as determined through considerable ELISA reactivity with S. cervi intact Mf. When tested under native conditions (immunoelectrophoresis and crossed immunoelectrophoresis), all the four immune rabbit sera were able to detect antigens of S. cervi Mf and adult stages.Conclusion:These results can be useful in detailed understanding of the complex nature of the Mf and adult antigens, which are prerequisites in the development of vaccine and more specific diagnostic tests.

Isolation and Chemical Characterization of a Capsular Polysaccharide Antigen Shared by Clinical Isolates ofEnterococcus faecalis and Vancomycin-ResistantEnterococcus faecium

ABSTRACT Enterococci are a common cause of serious infections, especially in newborns, severely immunocompromised patients, and patients requiring intensive care. To characterize enterococcal surface antigens that are targets of opsonic antibodies, rabbits were immunized with various gentamicin-killed Enterococcus faecalis strains, and immune sera were tested in an opsonophagocytic assay against a selection of clinical isolates. Serum raised against one strain killed the homologous strain (12030) at a dilution of 1:5,120 and mediated opsonic killing of 33% of all strains tested. In addition, this serum killed two (28%) of seven vancomycin-resistant Enterococcus faecium strains. Adsorption of sera with the homologous strain eliminated killing activity. The adsorbing antigens were resistant to treatment with proteinase K and to boiling for 1 h, but were susceptible to treatment with sodium periodate, indicating that the antigen inducing opsonic activity is a polysaccharide. Antibodies in immune rabbit sera reacted with a capsule-like structure visualized by electron microscopy both on the homologous E. faecalisstrain and on a vancomycin-resistant E. faecium strain. The capsular polysaccharides from E. faecalis 12030 andE. faecium 838970 were purified, and chemical and structural analyses indicated they were identical glycerol teichoic acid-like molecules with a carbohydrate backbone structure of 6-α-d-glucose-1-2 glycerol-3-PO4 with substitution on carbon 2 of the glucose with an α-2-1-d-glucose residue. The purified antigen adsorbed opsonic killing activity from immune rabbit sera and elicited high titers of antibodies (when used to immunize rabbits) that both mediated opsonic killing of bacteria and bound to a capsule-like structure visualized by electron microscopy. These results indicate that approximately one-third of a sample of 15 E. faecalisstrains and 7 vancomycin-resistant E. faecium strains possess shared capsular polysaccharides that are targets of opsonophagocytic antibodies and therefore are potential vaccine candidates.

Artifact-free electron microscopic immunocytochemistry on rat brain tissue

Electron microscopic immunocytochemistry provides an important tool to determine the ultrastructural distribution of various molecules in both normal and pathologic tissues. However, the specific immunostaining may be obscured by artifactual immunoreaction product, misleading the investigator. Previous observations show that shortening the incubation period with the primary antibody from the generally used 12-24 hours to 1 hour substantially reduces the artifactual immunostaining. We now extend this finding by the demonstration of artifact-free ultrastructural localization of the Ca2/calmodulindependent cyclic nucleotide phosphodiesterase (CaM-dependent PDE) immunoreactivity in brain.Anesthetized rats were perfused transcardially with phosphate-buffered saline followed by a fixative containing paraformaldehyde (4%) and glutaraldehyde (0.25%) in PBS. The brains were removed, and 40μm sections were cut with a vibratome. The sections were processed for immunocytochemistry as described by Ludvig et al. Both non-immune rabbit serum and specific CaM-dependent PDE antibodies were used. In both experiments incubations were at one hour and overnight. The immunostained sections were processed for electron microscopic examination.

Soluble factors from rabbit spleen cells kill and lyse Treponema pallidum in vitro

Antibody and complement immobilize (kill) Treponema pallidum in vitro. Recent evidence also documents immobilization by soluble factors released by activated macrophages and lymphocytes. Immune-mediated lysis of treponemes, however, has not been reported. The findings in this paper focus on apparent treponemal lysis by rabbit splenic cell preparations. Using cells from animals infected testicularly for 9 to 12 days, unfractionated splenic preparations, as well as adherent and nonadherent preparations, killed and lysed T. pallidum. Phagocytosis alone could not explain the detrimental effects of adherent cells. When cytochalasin B was used to block phagocytosis, decreases in treponemal numbers were still detected. In related studies, immune rabbit sera did not enhance treponemicidal activity of the adherent cells. To assess the specificity of these reactions, T. pallidum was incubated with two monocyte-like cell lines (human U937 and mouse P388D1). Neither cell line was detrimental, and treponemal numbers were not lowered. The soluble nature of the treponemicidal factors from adherent and nonadherent preparations was shown by physically separating these cells from the organisms and demonstrating treponemal killing and lysis. In summary, clearance of T. pallidum from infected tissues is probably at least partially attributed to macrophage phagocytosis. Our findings suggest another mechanism involving lytic factors secreted by activated adherent and nonadherent cells. Key words: syphilis, splenic treponemicidal activity, Treponema pallidum.