Design of a new multi-epitope vaccine against Brucella based on T and B cell epitopes using bioinformatics methods.

Brucellosis is one of the most serious and widespread zoonotic diseases, which seriously threatens human health and the national economy. This study was based on the T/B dominant epitopes of Brucella outer membrane protein 22 (Omp22), outer membrane protein 19 (Omp19) and outer membrane protein 28 (Omp28), with bioinformatics methods to design a safe and effective multi-epitope vaccine. The amino acid sequences of the proteins were found in the National Center for Biotechnology Information (NCBI) database, and the signal peptides were predicted by the SignaIP-5.0 server. The surface accessibility and hydrophilic regions of proteins were analysed with the ProtScale software and the tertiary structure model of the proteins predicted by I-TASSER software and labelled with the UCSF Chimera software. The software COBEpro, SVMTriP and BepiPred were used to predict B cell epitopes of the proteins. SYFPEITHI, RANKpep and IEDB were employed to predict T cell epitopes of the proteins. The T/B dominant epitopes of three proteins were combined with HEYGAALEREAG and GGGS linkers, and carriers sequences linked to the N- and C-terminus of the vaccine construct with the help of EAAAK linkers. Finally, the tertiary structure and physical and chemical properties of the multi-epitope vaccine construct were analysed. The allergenicity, antigenicity and solubility of the multi-epitope vaccine construct were 7.37-11.30, 0.788 and 0.866, respectively. The Ramachandran diagram of the mock vaccine construct showed 96.0% residues within the favoured and allowed range. Collectively, our results showed that this multi-epitope vaccine construct has a high-quality structure and suitable characteristics, which may provide a theoretical basis for future laboratory experiments.

Nanoparticle-Based Vaccines for Brucellosis: Calcium Phosphate Nanoparticles-Adsorbed Antigens Induce Cross Protective Response in Mice.

INTRODUCTION: Vaccine formulation with appropriate adjuvants is an attractive approach to develop protective immunity against pathogens. Calcium phosphate nanoparticles (CaPNs) are considered as ideal adjuvants and delivery systems because of their great potential for enhancing immune responses. In the current study, we have designed nanoparticle-based vaccine candidates to induce immune responses and protection against B. melitensis and B. abortus. MATERIALS AND METHODS: For this purpose, we used three Brucella antigens (FliC, 7α-HSDH, BhuA) and two multi-epitopes (poly B and poly T) absorbed by CaPNs. The efficacy of each formulation was evaluated by measuring humoral, cellular and protective responses in immunized mice. RESULTS: The CaPNs showed an average size of about 90 nm with spherical shape and smooth surface. The CaPNs-adsorbed proteins displayed significant increase in cellular and humoral immune responses compared to the control groups. In addition, our results showed increased ratio of specific IgG2a (associated with Th1) to specific IgG1 (associated with Th2). Also, immunized mice with different vaccine candidate formulations were protected against B. melitensis 16M and B. abortus 544, and showed same levels of protection as commercial vaccines (B. melitensis Rev.1 and B. abortus RB51) except for BhuA-CaPNs. DISCUSSION: Our data support the hypothesis that these antigens absorbed with CaPNs could be effective vaccine candidates against B. melitensis and B. abortus.

Mannosylated chitosan nanoparticles loaded with FliC antigen as a novel vaccine candidate against Brucella melitensis and Brucella abortus infection.

Brucellosis is a worldwide bacterial zoonosis disease. Live attenuated Brucella vaccines have several drawbacks. Thus development of a safe and effective vaccine for brucellosis is a concern of many scientists. FliC protein contributes in virulence of Brucella; hence, it is a promising target for brucellosis vaccine. In this study, Mannosylated Chitosan Nanoparticles (MCN) loaded with FliC protein were synthesized as a targeted vaccine delivery system. The immunogenicity and protective efficacy of FliC and FliC-MCN against Brucella infection were evaluated in BALB/c mice. After cloning, expression and purification, FliC protein was loaded on MCN. The particle size, loading efficiency and in vitro release of the NPs were determined. Our investigation revealed that FliC and FliC-MCN could significantly increase specific IgG response (higher IgG2a titers). Besides, spleen cells from immunized mice produced high level of IFN-γ and IL-2 and low level IL-10 cytokines. Immunization with FliC and FliC-MCN conferred significant degree of protection against B. melitensis 16 M and B. abortus 544 infections. Overall these results indicate that FliC protein would be a novel potential antigen candidate for the development of a subunit vaccine against B. melitensis and B. abortus. Moreover, MCN could be used as an adjuvant and targeted vaccine delivery system.

Potential druggable proteins and chimeric vaccine construct prioritization against Brucella melitensis from species core genome data.

The Brucella melitensis chronic infection and drug resistance emerged as a severe health problem in humans and domestic cattle. The pathogens fast genome sequences availability fetched the possibility to address novel therapeutics targets in a rationale way. We acquired the core genes set from 56 B. melitensis publically available complete genome sequences. A stringent bioinformatics layout of comparative genomics and reverse vaccinology was followed to identify potential druggable proteins and multi-epitope vaccine constructs from core genes. The 23 proteins were shortlisted as novel druggable targets based on their role in pathogen-specific metabolic pathways, non-homologous to human and human gut microbiome proteins and their druggability potential. Furthermore, potential chimeric vaccine constructs were generated from lead T and B-cell overlapped epitopes in combination with immune enhancer adjuvants and linkers sequences. The molecular docking and MD simulation analyses ensured stable molecular interaction of a finally prioritized vaccine construct with human immune cells receptors.

Enhancement of host infectivity, immunity, and protective efficacy by addition of sodium bicarbonate antacid to oral vaccine formulation of live attenuated Salmonella secreting Brucella antigens.

In the present study, the importance of sodium bicarbonate antacid as an agent for an orally delivered attenuated Salmonella strain secreting Brucella antigens Cu-Zn superoxide dismutase (SodC) and outer membrane protein 19 (Omp19) as a live vaccine candidate against Brucella infection was investigated. First, Brucella antigens SodC and Omp19 were cloned into a prokaryotic constitutive expression vector, pJHL65. Then secretion of proteins was verified after transformation into an attenuated Salmonella typhimurium (ST) strain, JOL1800 (Δlon, ΔcpxR, Δasd, ΔrfaL), using western blot analysis. Mice were orally inoculated with phosphate-buffered saline (PBS) or with a co-mixture Salmonella secreting each antigens at a 1:1 ratio, each containing 1 × 108 CFU/mouse with and without sodium bicarbonate treatment. For antacid treatment, 1.3% w/v sodium bicarbonate was orally administered 30 min before and immediately after immunization with the Salmonella formulation. Humoral and cell-mediated immune responses were evaluated to investigate the efficacy of sodium bicarbonate in an oral formulation. The results indicated that addition of sodium bicarbonate to the vaccine significantly increased (P < 0.05) levels of anti-Brucella-specific systemic IgG responses, lymphocyte proliferation, and CD4+ T cell responses, indicating induction of a mixed Th1-Th2 response. Immunohistochemical assays and bacterial enumeration in intestinal samples also indicated that administration of sodium bicarbonate enhanced colonization of Salmonella. These results indicate that ingestion of the Salmonella formulation with sodium bicarbonate can enhance colonization of Salmonella and induce a significant protective immune response against Brucella compared with a formulation without sodium bicarbonate. Thus, incorporation of sodium bicarbonate as an antacid buffer is highly recommended for this oral live vaccine.

Mucosal immunization with polymeric antigen BLSOmp31 using alternative delivery systems against Brucella ovis in rams.

Subcellular vaccines against ovine contagious epididymitis due Brucella ovis can solve some shortcomings associated with the use of Brucella melitensis Rev 1. We have demonstrated that the parenteral immunization with polymeric antigen BLSOmp31 emulsified in oil adjuvant conferred significant protection against B. ovis in rams. In our previous studies, we have characterized chitosan microspheres (ChMs) and a thermoresponsive and mucoadhesive in situ gel (Poloxamer 407-Ch) as two novel formulation strategies for the delivery of BLSOmp31 in nasal as well as conjunctival mucosa. In the present work, we evaluated the immunogenicity and protection conferred by the intranasal and conjunctival immunization with these two mucosal delivery systems against B. ovis in rams. BLSOmp31-ChM administered by intranasal route and BLSOmp31-P407-Ch applied by intranasal or conjunctival routes induced systemic, local and preputial IgG and IgA antibody response. Neither formulation showed interference in the serological diagnosis. Thus, mucosal immunization using either formulation induced significant specific cellular immune responses (in vitro and in vivo) and it prevented the excretion of B. ovis in semen. Although these vaccines did not prevent infection in immunized rams, colonization reduction of infected organs and bacterial distribution differed significantly between vaccinated and unvaccinated rams.

Effects of Thermoextracts of Brucella S and L Forms on Lipid Peroxidation and Antioxidant Defense in Organs of Laboratory Animals.

The dynamics of LPO marker malondialdehyde formation and peroxidase-destroying activity was studied in homogenized organs of guinea pigs, immunized with thermoextracts from S and L forms Brucella abortus I-206. The L form brucella thermoextract exhibited a lower reactogenicity and adequately activated the antioxidant system, due to which the destructive effects of ROS could be partially neutralized during the vaccinal process.

Brucellosis vaccines: assessment of Brucella melitensis lipopolysaccharide rough mutants defective in core and O-polysaccharide synthesis and export.

BACKGROUND: The brucellae are facultative intracellular bacteria that cause brucellosis, one of the major neglected zoonoses. In endemic areas, vaccination is the only effective way to control this disease. Brucella melitensis Rev 1 is a vaccine effective against the brucellosis of sheep and goat caused by B. melitensis, the commonest source of human infection. However, Rev 1 carries a smooth lipopolysaccharide with an O-polysaccharide that elicits antibodies interfering in serodiagnosis, a major problem in eradication campaigns. Because of this, rough Brucella mutants lacking the O-polysaccharide have been proposed as vaccines. METHODOLOGY/PRINCIPAL FINDINGS: To examine the possibilities of rough vaccines, we screened B. melitensis for lipopolysaccharide genes and obtained mutants representing all main rough phenotypes with regard to core oligosaccharide and O-polysaccharide synthesis and export. Using the mouse model, mutants were classified into four attenuation patterns according to their multiplication and persistence in spleens at different doses. In macrophages, mutants belonging to three of these attenuation patterns reached the Brucella characteristic intracellular niche and multiplied intracellularly, suggesting that they could be suitable vaccine candidates. Virulence patterns, intracellular behavior and lipopolysaccharide defects roughly correlated with the degree of protection afforded by the mutants upon intraperitoneal vaccination of mice. However, when vaccination was applied by the subcutaneous route, only two mutants matched the protection obtained with Rev 1 albeit at doses one thousand fold higher than this reference vaccine. These mutants, which were blocked in O-polysaccharide export and accumulated internal O-polysaccharides, stimulated weak anti-smooth lipopolysaccharide antibodies. CONCLUSIONS/SIGNIFICANCE: The results demonstrate that no rough mutant is equal to Rev 1 in laboratory models and question the notion that rough vaccines are suitable for the control of brucellosis in endemic areas.

Optimization of the entrapment of bacterial cell envelope extracts into microparticles for vaccine delivery.

The encapsulation of a Brucella ovis extract (HS) in microparticles has been proved effective against experimental infections in mice. This work describes different strategies to increase the HS loading and prepare large batches as necessary to test this vaccine in ovine. The mixture of HS with beta-cyclodextrin was optimized in order to increase the HS loading in microparticles. On the other hand, TROMS ('Total Recirculation One-Machine System') led microparticles with a more homogeneous size than the laboratory or standard procedure. Moreover, the initial burst release of HS from the standard microparticles was higher than for the TROMS ones. In fact, standard microparticles displayed a higher amount of adsorbed HS. On the contrary, both preparative methods were found effective to preserve the integrity and anti-genicity of the loaded HS. In summary, beta-CD can be used to increase the loading of large hydrophobic materials and TROMS is a valid large production of antigen-loaded microparticles.

Influence of the co-encapsulation of different excipients on the properties of polyester microparticle-based vaccine against brucellosis.

This work evaluates the influence of different pharmaceutical auxiliaries (Pluronic F68, polyvinylpyrrolidone [PVP] or Tween 20), when mixed with an antigenic extract from Brucella ovis (hot saline; HS), on the characteristics of the resulting poly(epsilon-caprolactone) (PEC) and poly(lactide-co-glycolide) (PLGA) microparticles. In all cases, PEC microparticles were smaller than PLGA ones. Concerning the HS loading, PLGA microparticles were highly dependent on the type of the excipient used, whereas all the PEC formulations displayed similar encapsulation efficiencies. For both types of microparticles, the presence of PVP induced a burst release effect. On the contrary, the use of Tween 20 or Pluronic F68 dramatically modified this profile. For PLGA-Tween 20 and PEC-Pluronic F68 microparticles, the HS was released in a pulsatil way during the first 7 days followed by a continuous release for at least 3 weeks. The antigenicity of the HS components was kept in all cases. Phagocytosis by murine monocytes showed a clear difference based just on the hydrophobicity of the polymer, being PEC microparticles better engulfed. Cell activation quantified by the release of H2O2 did not showed major differences between batches, however, microparticles of PEC and Pluronic F68 induced the highest nitric oxide production. Together, these results confirm the advantageous qualities of the "HS-PEC-Pluronic F68 microparticles" as favorable candidate for vaccine purposes against brucellosis.

Vacunas en la brucelosis humana / Vaccines in human brucellosis

Hace casi 100 años la brucelosis humana fue considerada por Zammit y Horrocks como una zoonosis, sólo 18 años después que Bruce identificó el agente etiológico de la fiebre de Malta. A lo largo de los años, el avance científico se ha visto encaminado primordialmente al control de la brucelosis animal en los aspectos de diagnóstico y vacunación. En cuanto a la enfermedad en el humano, el progreso más importante ha sido la quimioterapia, aunque en la última década el diagnóstico correcto ha sido un asunto de preocupación general. Las estrategias de erradicación de la brucelosis se divide en tres categorías: 1) Erradicación de la brucelosis animal; 2) Mejoramiento de las medidas de higiene individual y saneamiento y 3) Inmunización. Las vacunas contra la brucelosis han sido desarrolladas a lo largo de tres líneas: 1) vacunas vivas preparadas con cepas atenuadas como B. abortus cepa 19 y B. melitensis cepa Rev.1; 2) células completas inactivadas, como B. abortus cepa 45/20 y B. melitensis H-38 que se administran con adyuvante oleoso y 3) vacunas preparadas con fracciones celulares. Todas ellas han sido usadas ampliamente en el control de la brucelosis en animales y sólo en algunos casos muy particulares en humanos