[Study on the DNA vaccine against foot-and-mouth disease virus using the heavy chain constant region of swine IgG as the carrier for peptide epitopes].

The peptide of amino acids 141-160 of VP1 protein of foot-and-mouth disease virus (FMDV) is a major B cell epitope and the peptide of amino acids 21-40 is an important T cell epitope. In this study, the DNA fragments of 141-160 and 21-40 peptide epitopes of a strain of type O FMDV was chemically synthesized and arranged into a tandem repeat 141-160 (20AA)-21-40 (20AA)-141-160 (20AA). This tandem sequence was fused to the 3' end of the heavy chain constant region gene of swine immunoglobulin G and was then cloned into mammalian expression vector pCDM8 to form a recombinant plasmid pCDM8FZ3. After pCDM8FZ3 was inoculated intramuscularly into guinea pigs, it elicited a neutralizing antibody response and a specific spleen T cell proliferative response, and 66% of the vaccinated animals were protected from viral challenge. Our study indicated that the heavy chain constant region of swine IgG can act as the carrier protein for FMDV peptide epitopes, and pC-DM8FZ3 is a potential DNA vaccine candidate to prevent FMDV infection.

Plasmids encoding foot-and-mouth disease virus VP1 epitopes elicited immune responses in mice and swine and protected swine against viral infection.

VP1 is a capsid protein of foot-and-mouth disease virus (FMDV) and contains epitopes of the virus. Plasmids encoding two VP1 epitopes (amino acid residues 141-160 and 200-213) and a host-self immunoglobulin molecule were constructed to produce a new type of FMD DNA vaccine. Two plasmids, namely, pCEIM and pCEIS, containing mouse immunoglobulin (IgG) or swine IgG were subjected to immunogenicity testing in mice and swine, respectively. In mice administrated pCEIM in the abdomen using a genegun, both FMDV-specific T-cell proliferation and neutralizing antibodies were detected. In swine immunized with pCEIS at the back of the ear, immune responses were achieved after the second administration. Swine showed a T-cell proliferative response with a stimulation index (SI) of up to 8.1 and a neutralizing antibody response that was able to protect suckling mice from 10(2) LD(50) (lethal dose 50) FMDV challenge. To compare the immunogenicity of the DNA-based vaccine candidate, versus the protein-based vaccine candidates, a second group of swine was immunized with the protein F1-scIgG, which was encoded by the plasmid pCEIS. Injection with F1-scIgG elicited a T-cell proliferative response of SI < 1.7 and a neutralizing antibody response that protected suckling mice from up to 10(5) LD(50) FMDV challenge. In the challenge test, three of three swine immunized with pCEIS were fully protected from FMDV challenge.

An immunoglobulin G based chimeric protein induced foot-and-mouth disease specific immune response in swine.

Epitopes containing the residues 141aa-160aa and 200aa-213aa from foot-and-mouth disease (FMD) serotype O1K HK type FMDV VP1 were joined to a swine immunoglobulin G single heavy chain constant region (scIgG), creating a novel chimeric protein, named F1-scIgG. In this study, inoculation with F1-scIgG induced both FMD virus-neutralizing antibody response and T cell response in swine. Antisera from these F1-scIgG-inoculated swine protected suckling mice against 1000 lethal dose 50 (1000LD(50)) FMD challenge. F1-scIgG-inoculated swine were also fully protected against 50LD(50) FMD virus challenge. The present study demonstrates the clear potential for viral epitopes linked with self-Ig in novel FMD vaccine design.