Brucella suis strain 2 vaccine is safe and protective against heterologous Brucella spp. infections

Brucellosis is a wide spread zoonotic disease that causes abortion and infertility in mammals and leads to debilitating, febrile illness in humans. Brucella abortus, Brucella melitensis and Brucella suis are the major pathogenic species to humans. Vaccination with live attenuated B. suis strain 2 (S2) vaccine is an essential and critical component in the control of brucellosis in China. The S2 vaccine is very effective in preventing brucellosis in goats, sheep, cattle and swine. However, there are still debates outside of China whether the S2 vaccine is able to provide protection against heterologous virulent Brucella species. We investigated the residual virulence, immunogenicity and protective efficacy of the S2 vaccine in BALB/c mice by determining bacteria persistence in spleen, serum antibody response, cellular immune response and protection against a heterologous virulent challenge. The S2 vaccine was of low virulence as there were no bacteria recovered in spleen four weeks post vaccination. The vaccinated mice developed Brucella-specific IgG in 2–3 weeks, and a burst production of IFN-γ at one week as well as a two-fold increase in TNF-α production. The S2 vaccine protected mice from a virulent challenge by B. melitensis M28, B. abortus 2308 and B. suis S1330, and the S2 vaccinated mice did not develop any clinical signs or tissue damage. Our study demonstrated that the S2 vaccine is of low virulence, stimulates good humoral and cellular immunity and protects animals against infection by heterologous, virulent Brucella species.     

The degree of protection given by living vaccines against experimental infection with Brucella melitensis in goats

It has been shown by a number of workers that Brucella melitensis Rev. 1 vaccine confers good protection against infection with Br. melitensis in sheep and goats. Although Br. abortus strain 19 vaccine is widely used in some countries to protect sheep, it has not been evaluated for caprine brucellosis. The purpose of the experiment reported in this paper was to determine and compare the degree of protection given by living vaccines prepared from Rev. 1 and strain 19 and by a non-agglutinogenic strain of Br. melitensis against graded, experimental challenge in goats.     

Immunization of mice with gamma-irradiated Brucella neotomae and its recombinant strains induces protection against virulent B. abortus, B. melitensis, and B. suis challenge

Human brucellosis, a zoonotic disease of major public health concern in several developing countries, is primarily caused by Brucella abortus, Brucella melitensis, and Brucella suis. No brucellosis vaccine is available for human use. The aim of this study was to determine if Brucella neotomae, a bacterium not known to cause disease in any host, can be used for developing brucellosis vaccines. B. neotomae and its recombinant strains overexpressing superoxide dismutase and a 26 kDa periplasmic protein were rendered non-replicative through exposure to gamma-radiation and used as vaccines in a murine brucellosis model. All three vaccines induced antigen-specific antibody and T cell responses. The vaccinated mice showed significant resistance against challenge with virulent B. abortus 2308, B. melitensis 16 M, and B. suis 1330. These results demonstrate that the avirulent B. neotomae is a promising platform for developing a safe and effective vaccine for human brucellosis.     

B. melitensis rough strain B115 is protective against heterologous Brucella spp. infections

Brucellosis is one of the most serious zoonoses all over the world, with B. melitensis, B. abortus and B. suis being the most pathogenic species for humans. Vaccination of domesticated livestock still represents the most efficient way to prevent human infection. However, the available Brucella vaccines retain an important residual virulence and induce antibodies interfering with surveillance programs. Moreover, each vaccine shows different protective effects versus different Brucella species and different animal hosts.Nowadays, while B. melitensis and B. suis infections in cattle are emerging as a significant problem, there are no available vaccines to overcome such issue.B. melitensis strain B115, a natural, attenuated rough strain in our previous studies proved to be highly protective against B. melitensis and B. ovis infections in mice, without inducing interfering antibodies. In this study, we tested the efficiency of B115 as vaccine against B. abortus and B. suis. Vaccination of mice with 10⁸ CFU/mouse of B. melitensis B115 conferred a satisfactory protection against B. abortus 2308. On the contrary, mice vaccinated once with 10⁸ or 10⁹ CFU/mouse of B115 were weakly protected against B. suis infection. Conversely, when mice were vaccinated twice with 10⁹ CFU B115/mouse, the protective activity significantly increased. Unlike its rough phenotype, B115 showed an adequate persistence in mice accompanied to a solid humoral and cell-mediated immunity. All together, these findings suggest the potential usefulness of B115 to control brucellosis in animal hosts due to heterologous challenges.     

Development of a dual vaccine for prevention of Brucella abortus infection and Escherichia coli O157:H7 intestinal colonization

Zoonoses that affect human and animal health have an important economic impact. In the study now presented, a bivalent vaccine has been developed that has the potential for preventing the transmission from cattle to humans of two bacterial pathogens: Brucella abortus and Shiga toxin-producing Escherichia coli (STEC). A 66 kDa chimeric antigen, composed by EspA, Intimin, Tir, and H7 flagellin (EITH₇) from STEC, was constructed and expressed in B. abortus Δpgm vaccine strain (BabΔpgm). Mice orally immunized with BabΔpgm(EITH₇) elicited an immune response with the induction of anti-EITH₇ antibodies (IgA) that clears an intestinal infection of E. coli O157:H7 three times faster (t = 4 days) than mice immunized with BabΔpgm carrier strain (t = 12 days). As expected, mice immunized with BabΔpgm(EITH₇) strain also elicited a protective immune response against B. abortus infection. A Brucella-based vaccine platform is described capable of eliciting a combined protective immune response against two bacterial pathogens with diverse lifestyles—the intracellular pathogen B. abortus and the intestinal extracellular pathogen STEC.     

An influenza viral vector Brucella abortus vaccine induces good cross-protection against Brucella melitensis infection in pregnant heifers

Brucella melitensis can be transmitted and cause disease in cattle herds as a result of inadequate management of mixed livestock farms. Ideally, vaccines against Brucella abortus for cattle should also provide cross-protection against B. melitensis. Previously we created a novel influenza viral vector B. abortus (Flu-BA) vaccine expressing the Brucella ribosomal proteins L7/L12 or Omp16. This study demonstrated Flu-BA vaccine with adjuvant Montanide Gel01 provided 100% protection against abortion in vaccinated pregnant heifers and good cross-protection of the heifers and their calves or fetuses (90–100%) after challenge with B. melitensis 16 M; the level of protection provided by Flu-BA was comparable to the commercial vaccine B. abortus S19. In terms of the index of infection and colonization of Brucella in tissues, both vaccines demonstrated significant (P = 0.02 to P < 0.0001) protection against B. melitensis 16 M infection compared to the negative control group (PBS + Montanide Gel01). Thus, we conclude the Flu-BA vaccine provides cross-protection against B. melitensis infection in pregnant heifers.     

Immunization against Brucella infection: 10. The relative immunogenicity of Brucella abortus strain 19-BA and Brucella melitensis strain Rev I in Cynomolgus philippinensis*

Continuing previous studies, the authors investigated the immunogenicity of low doses of Brucella melitensis strain Rev I in Cynomolgus monkeys challenged by the respiratory route and compared the efficacy of Rev I vaccine with that of vaccine from Br. abortus strain 19-BA.     

Over-expression of homologous antigens in a leucine auxotroph of Brucella abortus strain RB51 protects mice against a virulent B. suis challenge

Infection by members of the Gram-negative bacterial genus Brucella causes brucellosis in a variety of mammals. Brucellosis in swine remains a challenge, as there is no vaccine in the USA approved for use in swine against brucellosis. Here, we developed an improved recombinant Brucella abortus vaccine strain RB51 that could afford protection against Brucella suis infection by over-expressing genes encoding homologous proteins: L7/L12 ribosomal protein, Cu/Zn superoxide dismutase [SOD] and glycosyl-transferase [WboA]. Using strain RB51leuB as a platform and an antibiotic-resistance marker free plasmid, strains RB51leuB/SOD, RB51leuB/SOD/L7/L12 and RB51leuB/SOD/WboA were constructed to over-express the antigens: SOD alone, SOD and ribosomal protein L7/L12 or SOD and glycosyl-transferase, respectively. The ability of these vaccine candidates to protect against a virulent B. suis challenge were evaluated in a mouse model. All vaccine groups protected mice significantly (P < 0.05) when compared to the control group. Within the vaccine groups, the mice vaccinated with strain RB51leuB/SOD/WboA were significantly better protected than those that were vaccinated with either strain RB51leuB/SOD or RB51leuB/SOD/L7/L12. These results suggest that Brucella antigens can be over-expressed in strain RB51leuB and elicit protective immune responses against brucellosis. Since the plasmid over-expressing homologous antigens does not carry an antibiotic resistance gene, it complies with federal regulations and therefore could be used to develop safer multi-species vaccines for prevention of brucellosis caused by other species of Brucella.     

Protective effect of a DNA vaccine containing an open reading frame with homology to an ABC-type transporter present in the genomic island 3 of Brucella abortus in BALB/c mice

The immunogenicity of a DNA vaccine containing an open reading frame (ORF) of genomic island 3 (GI-3), specific for Brucella abortus and Brucella melitensis, has been examined. Intramuscular injection of plasmid DNA carrying the open reading frame with homology to an ABC-type transporter (pV278a) into BALB/c mice elicited both humoral and cellular immune responses. Mice injected with pV278a had a dominant immunoglobulin G2a (IgG2a) response. This DNA vaccine elicited a T-cell-proliferative response and induced significant levels of interferon gamma (INF-γ) upon restimulation with recombinant 278a protein. Upon stimulation with an appropriate recombinant protein or crude Brucella protein, the vaccine did not induce IL-4, suggesting a typical T-helper (TH1) response. Furthermore, the vaccine induced protection in BALB/c mice when challenged with the virulent strain Brucella abortus 2308. Taken together, these data suggest that DNA vaccination offers an improved delivery of the homologous of an ABC-type transporter antigen, and provides the first evidence of a protective effect of this antigen in the construction of vaccines against B. abortus.     

Immunization against brucella infection: 7. Immunological and epidemiological studies in C��rdoba, Spain*

The author describes a study, carried out in the Province of Córdoba, Spain, to test the efficacy of a live vaccine prepared from the Rev I strain of Brucella melitensis against caprine brucellosis and to determine the extent of natural infection in goats and humans in the Province.     

Cell mediated immune response after challenge in Omp25 liposome immunized mice contributes to protection against virulent Brucella abortus 544

Brucellosis is a disease affecting various domestic and wild life species, and is caused by a bacterium Brucella. Keeping in view the serious economic and medical consequences of brucellosis, efforts have been made to prevent the infection through the use of vaccines. Cell-mediated immune responses [CMI] involving interferon gamma and cytotoxic CD4⁺ and CD8⁺ T cells are required for removal of intracellular Brucella. Omp25 has been reported to be involved in virulence of Brucella melitensis, Brucella abortus and Brucella ovis. In our previous study, we have shown the protective efficacy of recombinant Omp25, when administered intradermally. In this study, the recombinant Omp25 was formulated in PC–PE liposomes and PLGA microparticles, to enhance the protective immunity generated by it. Significant protection was seen with prime and booster liposome immunization in Balb/c mice against virulent B. abortus 544 as it was comparable to B. abortus S-19 vaccine strain. However, microparticle prime and booster immunization failed to give better protection when compared to B. abortus S-19 vaccine strain. This difference can be attributed to the stimulation of cell mediated immune response in PC–PE liposome immunized mice even after challenge which converted to cytotoxicity seen in CD4⁺ and CD8⁺ enriched lymphocytes. However, in PLGA microparticle immunized mice, cell mediated immunity was not generated after challenge as observed by decreased cytotoxicity of CD4⁺ and CD8⁺ enriched lymphocytes. Our study emphasizes on the importance of liposome encapsulating Omp25 immunization in conferring protection against B. abortus 544 challenge in Balb/c mice with a single dose immunization regimen.     

A genome-wide SNP-based phylogenetic analysis distinguishes different biovars of Brucella suis

Brucellosis is an important zoonotic disease caused by Brucella spp. Brucella suis is the etiological agent of porcine brucellosis. B. suis is the most genetically diverged species within the genus Brucella. We present the first large-scale B. suis phylogenetic analysis based on an alignment-free k-mer approach of gathering polymorphic sites from whole genome sequences. Genome-wide core-SNP based phylogenetic tree clearly differentiated and discriminated the B. suis biovars and the vaccine strain into different clades. A total of 16,756 SNPs were identified from the genome sequences of 54 B. suis strains. Also, biovar-specific SNPs were identified. The vaccine strain B. suis S2–30 is extensively used in China, which was discriminated from all biovars with the accumulation of the highest number of SNPs. We have also identified the SNPs between B. suis vaccine strain S2–30 and its closest homolog, B. suis biovar 513UK. The highest number of mutations (22) was observed in the phosphomannomutase (pmm) gene essential for the synthesis of O-antigen. Also, mutations were identified in several virulent genes including genes coding for type IV secretion system and the effector proteins, which could be responsible for the attenuated virulence of B. suis S2–30.     

Studies on recombinant glucokinase (r-glk) protein of Brucella abortus as a candidate vaccine molecule for brucellosis

Brucellosis is one of the most prevalent zoonotic diseases of worldwide distribution caused by the infection of genus Brucella. Live attenuated vaccines such as B. abortus S19, B. abortus RB51 and B. melitensis Rev1 are found most effective against brucellosis infection in animals, contriving a number of serious side effects and having chances to revert back into their active pathogenic form. In order to engineer a safe and effective vaccine candidate to be used in both animals and human, a recombinant subunit vaccine molecule comprising the truncated region of glucokinase (r-glk) gene from B. abortus S19 was cloned and expressed in Escherichia coli BL21DE3 host. Female BALB/c mice immunized with purified recombinant protein developed specific antibody titer of 1:64,000. The predominant IgG2a and IgG2b isotypes signified development of Th1 directed immune responses. In vitro cell cytotoxicity assay using anti-r-glk antibodies incubated with HeLa cells showed 81.20% and 78.5% cell viability against lethal challenge of B. abortus 544 and B. melitensis 16M, respectively. The lymphocyte proliferative assay indicated a higher splenic lymphocyte responses at 25 μg/ml concentration of protein which implies the elevated development of memory immune responses. In contrast to control, the immunized group of mice intra-peritoneal (I.P.) challenged with B. abortus 544 were significantly protected with no signs of necrosis and vacuolization in their liver and spleen tissue. The elevated B-cell response associated with Th1 adopted immunity, significant in vitro cell viability as well as protection afforded in experimental animals after challenge, supplemented with histopathological analysis are suggestive of r-glk protein as a prospective candidate vaccine molecule against brucellosis.     

Caprine immunization against brucellosis; a summary of experiments on the isolation,properties and behaviour of a vaccine strain

The ability of a streptomycin-non-dependent strain of Brucella melitensis to immunize goats against brucella infection and to protect against the abortion phenomenon was determined in a series of studies using both heat-killed and living cells of the strain. The data presented contrast the efficacy of both types of vaccine and demonstrate the importance of the relationship between mating date and date of vaccination in the prevention of abortion. Also included is an account of experiments on cross-immunity between infections induced by tubercle bacilli and brucellae, using monocytes from vaccinated and unvaccinated rabbits.     

Genetic diversity of Brucella abortus and Brucella melitensis in Kazakhstan using MLVA-16

Brucellosis is an endemic disease in Central Asia characterized by high infection rates in humans and animals. Currently, little is known about the genetic diversity of Brucella spp. circulating in the region, despite the high prevalence of brucellosis. This study aimed to analyze the genetic diversity of Brucella melitensis and Brucella abortus strains circulating in the Republic of Kazakhstan. We genotyped 128 B. melitensis and 124 B. abortus strains collected in regions with the highest prevalence of brucellosis. Genotyping was performed using multi-locus variable-number tandem-repeat analysis (MLVA). Analysis of a subset of 8 loci (MLVA-8) of 128 B. melitensis strains identified genotypes 42 (n = 108), 43 (n = 2), and 63 (n = 19) related to the ‘East Mediterranean’ group. An MLVA-16 assay sorted 128 B. melitensis strains into 25 different genotypes. Excluding one variable locus, MLVA-15 of B. melitensis was distinct from strains originating in the Mediterranean region; however, 77% of them were identical to strains isolated in China. A minimum spanning tree for B. melitensis using MLVA-15 analysis clustered the local strains together with strains previously collected in China. MLVA-8 analysis of 124 B. abortus strains identified them as genotype 36, suggesting Eurasian distribution of this lineage. Complete MLVA-16 assay analysis clustered the strains into five genotypes, revealing little diversity of B. abortus when compared on the global scale. A minimum spanning tree for B. abortus obtained using MLVA-15 analysis clustered the 2 most prevalent genotypes (n = 117) together with strains previously collected in China. Thus, MLVA analysis was used to characterize 252 strains of Brucella collected in Kazakhstan. The analysis revealed genetic homogeneity among the strains. Interestingly, identical MLVA-15 profiles were found in seemingly unrelated outbreaks in China, Turkey, and Kazakhstan. Further analysis is needed for better understanding of the epidemiology of brucellosis in Asia.     

Ability of Brucella abortus rough vaccine strains to elicit DC and innate immunity in lung using a murine respiratory model

Brucella abortus strains RB51 and RB51SOD are live attenuated vaccine strains which protect mice against virulent B. abortus strain 2308 intraperitoneal challenge. By comparison, limited information is available on how Brucella vaccines stimulate pulmonary immunity against respiratory infection, another route of exposure in humans. Therefore, in this study, we assessed the ability of intranasally delivered vaccine strains RB51 and RB51SOD to induce innate immunity. Based on parameters assessed, rough strain RB51 induces a better innate immune response in lung versus strain RB51SOD. Additional studies to further delineate strain RB51's ability to stimulate DC and adaptive immunity are warranted.     

Characterization of possible correlates of protective response against Brucella ovis infection in rams immunized with the B. melitensis Rev 1 vaccine

Vaccination with the live attenuated Brucella melitensis Rev 1 vaccine is used to control ovine brucellosis caused by Brucella ovis in sheep. The objective of this study was to identify possible correlates of protective response to B. ovis infection through the characterization by microarray hybridization and real-time RT-PCR of inflammatory and immune response genes differentially expressed in rams previously immunized with B. melitensis Rev 1 and experimentally challenged with B. ovis. Gene expression profiles were compared before and after challenge with B. ovis between rams protected and those vaccinated but found infected after challenge. The TLR10, Bak and ANXI genes were expressed at higher levels in vaccinated and protected rams. These genes provide possible correlates of protective response to B. ovis infection in rams immunized with the B. melitensis Rev 1 vaccine.     

ΔznuAΔpurE Brucella abortus 2308 mutant as a live vaccine candidate

To create a new, safe brucellosis live vaccine, a double mutant strain was constructed from Brucella abortus 2308. Using the ΔznuA B. abortus 2308 mutant, a second mutation was introduced by deleting purE gene. The ΔznuA ΔpurE B. abortus 2308 strain was less capable of surviving in macrophages. When evaluated in vivo, it was cleared within 8 weeks (wks) from mice, causing significantly less inflammation than spleens obtained from wild-type B. abortus 2308-infected mice. Furthermore, two doses of ΔznuA ΔpurE B. abortus 2308 conferred 0.79 log protection, similar to S19 as did a single dose of ΔznuA B. abortus 2308. Thus, this study shows the ΔznuA ΔpurE B. abortus 2308 strain to be a potential livestock vaccine candidate.     

Efficacy of vaccination strategies against intranasal challenge with Brucella abortus in BALB/c mice

Brucellosis is a zoonotic disease affecting 500,000 people worldwide annually. Inhalation of aerosol containing a pathogen is one of the major routes of disease transmission in humans. Currently there are no licensed human vaccines available. Brucella abortus strain RB51 is a USDA approved live attenuated vaccine against cattle brucellosis. In a mouse model, strain RB51 over-expressing superoxide dismutase (SOD) administered intraperitoneally (IP) has been shown to be more protective than strain RB51 against an IP challenge with B. abortus pathogenic strain 2308. However, there is lack of information on the ability of these vaccine strains to protect against intranasal challenge. With the long-term goal of developing a protective vaccine for animals and people against respiratory challenge of Brucella spp., we tested a number of different vaccination strategies against intranasal infection with strain 2308. We employed strains RB51 and RB51SOD to assess the efficacy of route, dose, and prime-boost strategies against strain 2308 challenge. Despite using multiple protocols to enhance mucosal and systemic protection, neither rough RB51 vaccine strains provided respiratory protection against intranasal pathogenic Brucella infection. However, intranasal (IN) administration of B. abortus vaccine strain 19 induced significant (p ≤ 0.05) pulmonary clearance of strain 2308 upon IN challenge infection compared to saline. Further studies are necessary to address host-pathogen interaction in the lung microenvironment and elucidate immune mechanisms to enhance protection against aerosol infection.     

Development of an auxotrophic,live-attenuated Brucella suis vaccine strain capable of expressing multimeric GnRH

Feral swine cost around $1.5 billion each year in agricultural, environmental, and personal property damages. They are also the most widespread carriers of the zoonotic disease brucellosis, which threatens both livestock bio-security and public health. Currently, there is no approved vaccine against brucellosis in pigs. This is a preliminary report on the development of a live-attenuated B. suis vaccine that could be employed to deliver heterologous antigens to control swine populations. An attenuated vaccine strain provided significant protection against B. suis challenge in mice. Leucine auxotrophy in the vaccine strain allowed the over-expression of heterologous antigens without the use of antibiotic resistant markers. Vaccinated mice showed the development of antibodies against expressed antigen. Further evaluation is required to assess its ability to cause infertility using the mouse model prior to further testing for use as a tool for feral swine population and disease control.