Team:Slovenia/Results/Real-life results
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Latest revision as of 04:54, 30 October 2008
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Expression of DNA vaccine coding for multi-TMTIR4-GFP immunogen is detected in vivo in animals using non-invasive optical imaging. DNA vaccine construct (multi-TMTIR4-GFP) tagged with the reporter GFP gene was electroporated into the right leg muscle musculus tibialis cranialis. (A) Transcutaneous image under fluorescent stereoscope – arrows indicate GFP expression. (B) Same area as in part A but the image was taken under the white light illumination. (C) Positive control: leg muscle electroporated with a plasmid coding for an enhanced GFP reporter gene (pEGFP-N1, Clontech laboratories USA) showing areas of GFP expression (arrows).
To explore the potential of CF-multi and CF-UreB recombinant protein as an effective vaccine for prophylactic protection of C57BL/6J mice against prospective infection with H. pylori, serum IgG antibody responses were examined by ELISA. Samples were collected in the third week after the first vaccination. CF-multi (Fig. A), UreB (Fig. B) and heat-killed whole cell preparations of H. pylori were used as antigens for coating. Non-immunized mice served as controls. Dilution series and antibody titers of anti-CF-multi protein vaccine are presented in Fig. A below whereas titers of anti-CF-UreB antibodies are shown in Fig. B below. Results unequivocally demonstrate that the prophylactic immunization with both engineered chimeric flagellin recombinant proteins induced a significant increase in antigen-specific serum IgG antibodies already 3 weeks post vaccination suggesting an intense immune response to our vaccines. Moreover, anti-CF-multi and anti-CF-UreB antibodies also reacted with heat-killed H. pylori antigens as well as with living bacteria, which was demonstrated also by flow cytometry (see below). This implies that serum antibodies recognize not only purified recombinant protein molecules (Figs. A and B), but also native epitopes of H. pylori. This result suggests that vaccination with our engineered recombinant proteins should be capable of establishing immune system memory to mobilize relevant immune cells once an animal is challenged with H. pylori infection.
Additionally, we tested whether sera of mice immunized with CF-multi contained antibodies specific for ureaseB (Fig.C) and whether sera of mice immunized with CF-UreB (Fig. D) contained antibodies specific for chimeric flagellin. Indeed, ELISA test showed that both, urease B epitope and chimeric flagellin induce serum antibody production as shown in the figures below.
Immunization with flagellin-fused multiepitope produces antibodies that crossreact with whole urease B and vice versa. Histogram presents mean OD value measured at 450 nm and standard deviation. Sera of mice, vaccinated with CF-multi, crossreacted with UreB, (Fig. C) and sera of mice, vaccinated with CF-UreB, crossreacted with CF-multi coating (Fig. D), demonstrating the validity of designed multiepitope approach.
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