Transgenic papaya: a useful platform for oral vaccines

The development of effective delivery systems to cope with the reduced immunogenicity of new subunit vaccines is a priority in vaccinology. Herein, experimental evidence supporting a papaya-based platform to produce needle-free, recombinant, highly immunogenic vaccines is shown. Papaya (Carica papay...

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Bibliographic Details
Published in:Planta 2017-05, Vol.245 (5), p.1037-1048
Main Authors: Fragoso, Gladis, Hernández, Marisela, Cervantes-Torres, Jacquelynne, Ramírez-Aquino, Rubén, Chapula, Héctor, Villalobos, Nelly, Segura-Velázquez, René, Figueroa, Alfredo, Flores, Iván, Jiménez, Herminio, Adalid, Laura, Rosas, Gabriela, Galvez, Luis, Pezzat, Elias, Monreal-Escalante, Elizabeth, Rosales-Mendoza, Sergio, Vazquez, Luis G., Sciutto, Edda
Format: Article
Language:English
Subjects:
Administration, Oral
Agriculture
Animals
Antigens, Helminth - administration & dosage
Antigens, Helminth - immunology
Biomedical and Life Sciences
Carica - genetics
Carica - immunology
Carica - metabolism
Carica papaya
Cysticercosis - parasitology
Cysticercosis - prevention & control
Cysticercosis - veterinary
Ecology
Female
Forestry
Hypersensitivity
Immunization
Immunogenicity
Life Sciences
Liquid chromatography
Lymphocytes
Male
Mice
Mice, Inbred BALB C
ORIGINAL ARTICLE
Peptides
Plant Sciences
Plants, Genetically Modified
Swine
Swine Diseases - parasitology
Swine Diseases - prevention & control
Taenia solium
Taenia solium - immunology
Vaccines
Vaccines, Synthetic - administration & dosage
Vaccines, Synthetic - immunology
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Summary:The development of effective delivery systems to cope with the reduced immunogenicity of new subunit vaccines is a priority in vaccinology. Herein, experimental evidence supporting a papaya-based platform to produce needle-free, recombinant, highly immunogenic vaccines is shown. Papaya (Carica papaya) callus lines were previously engineered by particle bombardment to express the three protective peptides of the S3Pvac anti-cysticercosis vaccine (KETc7, KETc12, KETc1). Calli were propagated in vitro, and a stable integration and expression of the target genes has been maintained, as confirmed by PCR, qRT-PCR, and HPLC. These results point papaya calli as a suitable platform for long-term transgenic expression of the vaccine peptides. The previously demonstrated protective immunogenic efficacy of S3Pvac-papaya orally administered to mice is herein confirmed in a wider dose-range and formulated with different delivery vehicles, adequate for oral vaccination. This protection is accompanied by an increase in anti-S3Pvac antibody titers and a delayed hypersensitivity response against the vaccine. A significant increase in CD4+ and CD8+ lymphocyte proliferation was induced in vitro by each vaccine peptide in mice immunized with the lowest dose of S3Pvac papaya (0.56 ng of the three peptides in 0.1 lg of papaya callus total protein per mouse). In pigs, the obliged intermediate host for Taenia solium, S3Pvac papaya was also immunogenic when orally administered in a two-log dose range. Vaccinated pigs significantly increased anti-vaccine antibodies and mononuclear cell proliferation. Overall, the oral immunogenicity of this stable S3Pvac-papaya vaccine in mice and pigs, not requiring additional adjuvants, supports the interest in papaya callus as a useful platform for plant-based vaccines.
ISSN:0032-0935
1432-2048
DOI:10.1007/s00425-017-2658-z