SagE induces highly effective protective immunity against Streptococcus iniae mainly through an immunogenic domain in the extracellular region
Autor: | Yun Sun, Ming-qing Xing, Chun-sheng Liu, Li Sun, Yong-hua Hu |
---|---|
Rok vydání: | 2013 |
Předmět: |
Fish Proteins
DNA vaccine Virulence Flounder Biology Microbiology DNA vaccination Fish Diseases Immunity Streptococcal Infections Vaccines DNA Animals Streptococcus iniae Immune response Pathogen General Veterinary SAGE Research Streptococcal Vaccines Streptococcus General Medicine biology.organism_classification Virology Antibodies Bacterial Protein Structure Tertiary Vaccination Gene Expression Regulation Streptolysin Plasmids |
Zdroj: | Acta Veterinaria Scandinavica |
ISSN: | 1751-0147 |
Popis: | Background Streptococcus iniae is a Gram-positive bacterium and a severe pathogen of a wide range of farmed fish. S. iniae possesses a virulence-associated streptolysin S cluster composed of several components, one of which is SagE. SagE a transmembrane protein with one major extracellular region named ECR. This study aimed to develop a SagE-based DNA candidate vaccine against streptococcosis and examine the immunoprotective mechanism of the vaccine. Results We constructed a DNA vaccine, pSagE, based on the sagE gene and examined its immunological property in a Japanese flounder (Paralichthys olivaceus) model. The results showed that at 7 days post-vaccination, expression of SagE at transcription and translation levels was detected in the tissues of the vaccinated fish. After challenge with S. iniae at one and two months post-vaccination, pSagE-vaccinated fish exhibited relative percent survival (RPS) of 95% and 88% respectively. Immunological analysis showed that (i) pSagE significantly upregulated the expression of a wide range of immune genes, (ii) pSagE induced the production of specific serum antibodies that bound whole-cell S. iniae, and (iii) treatment of S. iniae with pSagE-induced antibodies blocked bacterial invasion of host cells. To localize the immunoprotective domain of SagE, the ECR-expressing DNA vaccine pSagEECR was constructed. Immunization analysis showed that flounder vaccinated with pSagEECR exhibited a RPS of 68%, and that pSagEECR induced serum antibody production and immune gene expression in a manner similar to, though to lower magnitudes than, those induced by pSagE. Conclusions We in this study developed a DNA vaccine, pSagE, which induces highly protective immunity against S. iniae. The protective effect of pSagE is probably due to its ability to elicit systemic immune response, in particular that of the humoral branch, which leads to production of specific serum antibodies that impair bacterial infection. These results add insights to the immunoprotective mechanism of fish DNA vaccine. |
Databáze: | OpenAIRE |
Externí odkaz: |