Development of Yersinia pestis F1 antigen-loaded microspheres vaccine against plague.

Yersinia pestis F1 antigen-loaded poly(DL-lactide-co-glycolide)/polyethylene glycol (PEG) (PLGA/PEG) microspheres were produced using a water-in-oil-in-water emulsion/solvent extraction technique and assayed for their percent yield, entrapment efficiency, surface morphology, particle size, zeta potential, in vitro release properties, and in vivo animal protect efficacy. The Y. pestis F1 antigen-loaded microspheres (mean particle size 3.8 µm) exhibited a high loading capacity (4.5% w/w), yield (85.2%), and entrapment efficiency (38.1%), and presented a controlled in vitro release profile with a low initial burst (18.5%), then continued to release Y. pestis F1 antigen over 70 days. The distribution (%) of Y. pestis F1 on the microspheres surface, outer layer, and core was 3.1%, 28.9%, and 60.7%, respectively. A steady release rate was noticed to be 0.55 µg Y. pestis F1 antigen/mg microspheres/day of Y. pestis F1 antigen release maintained for 42 days. The cumulative release amount at the 1st, 28th, and 42nd days was 8.2, 26.7, and 31.0 µg Y. pestis F1 antigen/mg microspheres, respectively. The 100 times median lethal dose 50% (LD50) of Y. pestis Yokohama-R strain by intraperitoneal injection challenge in mice test, in which mice received one dose of 40 µg F1 antigen content of PLGA/PEG microspheres, F1 antigen in Al(OH)3, and in comparison with F1 antigen in Al(OH)3 vaccine in two doses, was evaluated after given by subcutaneous immunization of BALB/c mice. The study results show that the greatest survival was observed in the group of mice immunized with one dose of F1 antigen-loaded PLGA/PEG microspheres, and two doses of F1 antigen in Al(OH)3 vaccine (100%). In vivo vaccination studies also demonstrated that F1 vaccines microspheres had a protective ability; its steady-state IgG immune protection in mice plasma dramatic increased from 2 weeks (18,764 ± 3,124) to 7 weeks (126,468 ± 19,176) after vaccination. These findings strongly suggest that F1-antigen loaded microspheres vaccine offer a new therapeutic strategy in optimizing the vaccine incorporation and delivery properties of these potential vaccine targeting carriers.

Evaluation of protective efficacy using a nonstructural protein NS1 in DNA vaccine-loaded microspheres against dengue 2 virus.

Dengue virus results in dengue fever or severe dengue hemorrhagic fever/dengue shock syndrome in humans. The purpose of this work was to develop an effective antidengue virus delivery system, by designing poly (dl-lactic-co-glycolic) acid/polyethylene glycol (PLGA/PEG) microspheres using a double-emulsion solvent extraction method, for vaccination therapy based on locally and continuously sustained biological activity. Nonstructural protein 1 (NS1) in deoxyribonucleic acid (DNA) vaccine-loaded PLGA/PEG microspheres exhibited a high loading capacity (4.5% w/w), yield (85.2%), and entrapment efficiency (39%), the mean particle size 4.8 µm, and a controlled in vitro release profile with a low initial burst (18.5%), lag time (4 days), and continued released protein over 70 days. The distribution of protein on the microspheres surface, outer layer, and core were 3.0%, 28.5%, and 60.7%, respectively. A release rate was noticed to be 1.07 µg protein/mg microspheres/day of protein release, maintained for 42 days. The cumulative release amount at Days 1, 28, and 42 was 18.5, 53.7, and 62.66 µg protein/mg microspheres, respectively. The dengue virus challenge in mice test, in which mice received one dose of 20 µg NS1 protein content of microspheres, in comparison with NS1 protein in Al(OH)3 or PBS solution, was evaluated after intramuscular immunization of BALB/c mice. The study results show that the greatest survival was observed in the group of mice immunized with NS1 protein-loaded PLGA/PEG microspheres (100%). In vivo vaccination studies also demonstrated that NS1 protein-loaded PLGA/PEG microspheres had a protective ability; its steady-state immune protection in rat plasma changed from 4,443 ± 1,384 pg/mL to 10,697 ± 3,197 pg/mL, which was 2.5-fold higher than that observed for dengue virus in Al(OH)3 at 21 days. These findings strongly suggest that NS1 protein-loaded PLGA/PEG microspheres offer a new therapeutic strategy in optimizing the vaccine incorporation and delivery properties of these potential vaccine targeting carriers.

Enhanced immune response by amphotericin B following NS1 protein prime-oral recombinant Salmonella vaccine boost vaccination protects mice from dengue virus challenge.

A recombinant vaccine strain SL3261/pLT105 of attenuated aroA Salmonella enterica serovar Typhimurium SL3261 strain expressing a secreted dengue virus type 2 non-structural NS1 and Yersinia pestis F1 (Caf1) fusion protein, rNS1:Caf1, was generated. Immunological evaluation was performed by prime-boost vaccine regimen. Oral immunization of mice with 1 x 10(9)cfu of SL3261/pLT105 only induced low levels of NS1-specific antibody response and protective immunity following dengue virus challenge. The parenteral NS1 protein priming-oral Salmonella boosting protocol enhanced both NS1-specific serum IgG response and protective efficacy as compared to mice immunized with each type vaccine alone. Addition of an antifungal antibiotic amphotericin B (AmB) to Salmonella vaccine further enhanced the synergic effects of prime-boost vaccine regimen on the elicited NS1-specific serum IgG response and the protective efficacy. Together, the results demonstrated that the rNS1:Caf1 producing Salmonella SL3261/pLT105 strain fails to provide effective protection as an oral vaccine alone despite co-administration of AmB as an adjuvant capable of enhancing the immune responses, and moreover, the protein priming-oral Salmonella vaccine boosting approach in combination with AmB as an immunization regimen may have the potential to be further explored as an alternative approach for dengue vaccine development.