Brucellosis vaccines based on the open reading frames from genomic island 3 of Brucella abortus.

Brucella abortus is the etiological agent of brucellosis, a zoonotic disease affecting cattle and humans. This disease has been partially controlled in cattle by immunization with live attenuated B. abortus S19 and RB51 strains. However, use of these vaccine strains has been associated with safety issues in animals and humans. New vaccines have since emerged in the prevention of brucellosis, particularly DNA vaccines, which have shown effectiveness and a good safety profile. Their protection efficacy in mice is associated with the induction of Th1 type and cytotoxic T cell mediated immune response against structural antigens and virulence factors expressed during B. abortus infection. Some antigenic candidate for vaccine design against brucellosis (mainly DNA vaccines) have been obtained from genomic island 3 (GI-3) of B. abortus, which encodes several open reading frames (ORFs) involved in the intracellular survival and virulence of this pathogen. The immunogenicity and protection conferred by these DNA vaccines in a murine model is reviewed in this article, suggesting that some of them could be safe and effective vaccine candidates against to prevent B. abortus infection.

Brucella abortus lysed cells using GI24 induce robust immune response and provide effective protection in Beagles.

The aim of the present study is to estimate the protective efficacy of Brucella abortus lysed cells by GI24 against brucellosis in Beagles. Group A was subcutaneously (sc) immunized with sterile phosphate-buffered saline, and group B was sc immunized with approximately 3 × 109 of the lysed cells. Brucella-LPS-specific serum IgG titers and IL-4, TNF-α and IFN-γ concentrations were investigated by enzyme linked immunosorbent assay. All dogs were intraconjunctivally challenged with B. abortus strain 544 at 6 weeks post-prime immunization. The serum IgG titers were considerably higher in group B than in group A. The levels of IL-4, TNF-α and IFN-γ in group B than in group A were significantly higher. Following challenge, no challenge strain was observed from all tissues of three dogs of group B. However, challenge strain was detected from spleen, uterus (except one Beagle) and inguinal and retropharyngeal lymph nodes of all group A Beagles. The results of this study demonstrated that sc immunization with the lysed cells induced robust antibody and cell-mediated immune responses in Beagles. The lysed cells also conferred protection against infection with B. abortus. These results suggest that sc immunization with B. abortus lysed cells by GI24 is a good vaccine candidate against brucellosis in dogs.

Evaluation of a hypervariable octameric oligonucleotide fingerprints assay for identification of and discrimination between wild-type and vaccine strains of Brucella melitensis.

OBJECTIVE To evaluate a hypervariable octameric oligonucleotide fingerprints (HOOF-Prints) assay for identification of and discrimination between wild-type and vaccine strains of Brucella melitensis. SAMPLE Brucella melitensis vaccine strain M5 and wild-type strain M43. PROCEDURES 8 pairs of primers (alterable, octameric nucleotides) were designed on the basis of a biological analysis of 8 flanking sequences in the DNA of B melitensis. The HOOF-Prints technique was used to identify wild-type and vaccine strains of B melitensis. Phylogenetic analysis of short, polymorphic fragments of DNA from B melitensis strains M5 and M43 was performed. RESULTS Variable-number tandem repeat DNA segments of B melitensis vaccine strain M5 and wild-type strain M43 were successfully amplified by means of PCR assay. All target gene fragments ranged in size from 100 to 300 bp. Separate phylogenetic analysis of each Brucella strain revealed considerable differences between the vaccine and wild-type strains. CONCLUSIONS AND CLINICAL RELEVANCE The results of this study suggested the HOOF-Prints assay may be useful for discriminating vaccine strains of B melitensis from wild-type strains. This ability could allow discrimination between animals that are seropositive because of vaccination against B melitensis and those that are seropositive because of B melitensis infection and could decrease the likelihood of importing Brucella-infected animals.

Booster vaccination with safe, modified, live-attenuated mutants of Brucella abortus strain RB51 vaccine confers protective immunity against virulent strains of B. abortus and Brucella canis in BALB/c mice.

Brucella abortus attenuated strain RB51 vaccine (RB51) is widely used in prevention of bovine brucellosis. Although vaccination with this strain has been shown to be effective in conferring protection against bovine brucellosis, RB51 has several drawbacks, including residual virulence for animals and humans. Therefore, a safe and efficacious vaccine is needed to overcome these disadvantages. In this study, we constructed several gene deletion mutants (ΔcydC, ΔcydD and ΔpurD single mutants, and ΔcydCΔcydD and ΔcydCΔpurD double mutants) of RB51 with the aim of increasing the safety of the possible use of these mutants as vaccine candidates. The RB51ΔcydC, RB51ΔcydD, RB51ΔpurD, RB51ΔcydCΔcydD and RB51ΔcydCΔpurD mutants exhibited significant attenuation of virulence when assayed in murine macrophages in vitro or in BALB/c mice. A single intraperitoneal immunization with RB51ΔcydC, RB51ΔcydD, RB51ΔcydCΔcydD or RB51ΔcydCΔpurD mutants was rapidly cleared from mice within 3 weeks, whereas the RB51ΔpurD mutant and RB51 were detectable in spleens until 4 and 7 weeks, respectively. Vaccination with a single dose of RB51 mutants induced lower protective immunity in mice than did parental RB51. However, a booster dose of these mutants provided significant levels of protection in mice against challenge with either the virulent homologous B. abortus strain 2308 or the heterologous Brucella canis strain 26. In addition, these mutants were found to induce a mixed but T-helper-1-biased humoral and cellular immune response in immunized mice. These data suggest that immunization with a booster dose of attenuated RB51 mutants provides an attractive strategy to protect against either bovine or canine brucellosis.

Immunization of mice with a novel recombinant molecular chaperon confers protection against Brucella melitensis infection.

Brucella spp. are zoonotic Gram-negative intracellular pathogens with the ability to survive and replicate in phagocytes. It has been shown that bacterial proteins expressed abundantly in this niche are stress-related proteins capable of triggering effective immune responses. BMEI1549 is a molecular chaperone designated DnaK that is expressed under stress conditions and helps to prevent formation of protein aggregates. In order to study the potential of DnaK as a prospective Brucella subunit vaccine, immunogenicity and protective efficacy of recombinant DnaK from Brucella melitensis was evaluated in BALB/c mice. The dnak gene was cloned, expressed in Escherichia coli, and the resulting recombinant protein used as subunit vaccine. DnaK-immunized mice showed a strong lymphocyte proliferative response to in vitro antigen stimulation. Although comparable levels of antigen-specific IgG2a and IgG1 were observed in immunized mice, high amounts of IFN-γ, IL-12 and IL-6, no detectable level of IL-4 and very low levels of IL-10 and IL-5 were produced by splenocytes of vaccinated mice suggesting induction of a Th1 dominant immune response by DnaK. Compared to control animals, mice vaccinated with DnaK exhibited a significant degree of protection against subsequent Brucella infection (p<0.001), albeit this protection was less than the protection conferred by Rev.1 (p<0.05). A further increase in protection was observed, when DnaK was combined with recombinant Omp31. Notably, this combination, as opposed to each component alone, induced statistically similar level of protection as induced by Rev.1 suggesting that DnaK could be viewed as a promising candidate for the development of a subunit vaccine against brucellosis.

Characterization and protective property of Brucella abortus cydC and looP mutants.

Brucella abortus readily multiplies in professional or nonprofessional phagocytes in vitro and is highly virulent in mice. Isogenic mutants of B. abortus biovar 1 strain IVKB9007 lacking the ATP/GDP-binding protein motif A (P-loop) (named looP; designated here the IVKB9007 looP::Tn5 mutant) and the ATP-binding/permease protein (cydC; designated here the IVKB9007 cydC::Tn5 mutant) were identified and characterized by transposon mutagenesis using the mini-Tn5Km2 transposon. Both mutants were found to be virtually incapable of intracellular replication in both murine macrophages (RAW264.7) and the HeLa cell line, and their virulence was significantly impaired in BALB/c mice. Respective complementation of the IVKB9007 looP::Tn5 and IVKB9007 cydC::Tn5 mutants restored their ability to survive in vitro and in vivo to a level comparable with that of the wild type. These findings indicate that the cydC and looP genes play important roles in the virulence of B. abortus. In addition, intraperitoneal immunization of mice with a dose of the live IVKB9007 looP::Tn5 and IVKB9007 cydC::Tn5 mutants provided a high degree of protection against challenge with pathogenic B. abortus strain 544. Both mutants should be evaluated further as a live attenuated vaccine against bovine brucellosis for their ability to stimulate a protective immune response.

[Experimental evaluation of the brucellosis therapeutic vaccine efficacy].

Use of antibiotics can't completely solve the problem of brucellosis treatment, especially its chronic forms, because antibacterial preparations do not eliminate main pathogenetic factor of the disease--sensibilization of the macroorganism. It makes actual the question about complex immuno- and antibacterial therapy. Long-term clinical experience proved high effectiveness of a therapeutic brucellosis vaccine. Earlier this preparation was manufactured in Research Institute of Vaccines and Sera in Tbilisi (Georgia). To date new composition of components of the vaccine has been developed, and manufacturing and control methods have been improved. Marked desensitizing effect of the vaccine and its stimulatory action on cellular and humoral immunity has been observed. In 2002 technological normative documentation for manufacturing and use of the vaccine was developed in the Research Institute of Microbiology (Kirov) and production of the vaccine began.

Increases of efficacy as vaccine against Brucella abortus infection in mice by simultaneous inoculation with avirulent smooth bvrS/bvrR and rough wbkA mutants.

The Brucella abortus S19 and RB51 strains are the most widely used live vaccines against bovine brucellosis. However, both can induce abortion and milk excretion, S19 vaccination interferes in serological tests, and RB51 is less effective. We have shown previously that a rough wbkAB. abortus mutant is attenuated and a better vaccine than RB51 in BALB/c mice, and that mutants in the two-component regulatory system bvrS/bvrR are markedly attenuated while keeping a smooth lipopolysaccharide (S-LPS). In this work, we tested whether simultaneous inoculation with live bvrS increases wbkA vaccine efficacy in mice. Even at high doses, the bvrS mutant was cleared much faster from spleens than the wbkA mutant. The splenic persistence of the wbkA mutant increased when inoculated along with the bvrS mutant, but also with inactivated bvrS cells or with purified B. abortus S-LPS, strongly suggesting that S-LPS in the bvrS mutant played a determinant role in the wbkA persistence. When inoculated alone, both mutants protected against virulent B. abortus but less than when inoculated simultaneously, and the protection afforded by the combination was better than that obtained with B. abortus S19. Increased protection was also obtained after simultaneous inoculation of the wbkA mutant and inactivated bvrS cells or purified S-LPS, showing again the role played by the S-LPS in the bvrS cells. In mice, the bvrS-wbkA combination induced an antibody response reduced with respect to B. abortus S19 vaccination. Thus, the simultaneous use of live bvrS and wbkA B. abortus mutants seems a promising approach to overcome the problems of the S19 andRB51 vaccines.

Protection of BALB/c mice against Brucella abortus 544 challenge by vaccination with bacterioferritin or P39 recombinant proteins with CpG oligodeoxynucleotides as adjuvant.

The P39 and the bacterioferrin (BFR) antigens of Brucella melitensis 16M were previously identified as T dominant antigens able to induce both delayed-type hypersensivity in sensitized guinea pigs and in vitro gamma interferon (IFN-gamma) production by peripheral blood mononuclear cells from infected cattle. Here, we analyzed the potential for these antigens to function as a subunitary vaccine against Brucella abortus infection in BALB/c mice, and we characterized the humoral and cellular immune responses induced. Mice were injected with each of the recombinant proteins alone or adjuvanted with either CpG oligodeoxynucleotides (CpG ODN) or non-CpG ODN. Mice immunized with the recombinant antigens with CpG ODN were the only group demonstrating both significant IFN-gamma production and T-cell proliferation in response to either Brucella extract or to the respective antigen. The same conclusion holds true for the antibody response, which was only demonstrated in mice immunized with recombinant antigens mixed with CpG ODN. The antibody titers (both immunoglobulin G1 [IgG1] and IgG2a) induced by P39 immunization were higher than the titers induced by BFR (only IgG2a). Using a B. abortus 544 challenge, the level of protection was analyzed and compared to the protection conferred by one immunization with the vaccine strain B19. Immunization with P39 and CpG ODN gave a level of protection comparable to the one conferred by B19 at 4 weeks postchallenge, and the mice were still significantly protected at 8 weeks postchallenge, although to a lesser extent than the B19-vaccinated group. Intriguingly, no protection was detected after BFR vaccination. All other groups did not demonstrate any protection.

Brucella melitensis Rev. 1 living attenuated vaccine: stability of markers, residual virulence and immunogenicity in mice.

Five commercial Brucella melitensis Rev. 1 vaccines from different sources were compared to the original Elberg Rev. 1 strain, in vitro for classic markers and in vivo in mice, for residual virulence and immunogenicity. Because colonies of several morphology types (smooth, non-smooth) were isolated from the vaccines, representative substrains were purified to study their in vitro and in vivo activities either at once (16 strains), or after storage by subculture (12 strains) and by lyophilization (eight strains) or after passage in mice (six strains). After purification, five strains had the characteristic pattern of resistance to penicillin and streptomycin of the original strain while 11 differed by a two-fold dilution or more. A few modifications only occurred after storage or passage. Residual virulence--the time taken by 50% of the subcutaneously vaccinated mice to eradicate the strain from their spleen--or recovery time 50%, and immunogenicity--the ability of the vaccinated mice to restrict the spleen count 15 days after a virulent intraperitoneal challenge--were compared on eight strains after purification, subculture and lyophilization. After purification, one smooth strain out of five had the same activities as the original strain and three were as immunogenic but less virulent. One smooth strain and the three non-smooth were neither immunogenic nor virulent. Some strains which were typically non-smooth after purification recovered a smooth phase aspect after subculture, concomitantly with an increase in immunogenicity but not in virulence.(ABSTRACT TRUNCATED AT 250 WORDS)

Temporal ELISA response of rams to Brucella ovis following experimental infection or vaccination.

Sera from rams vaccinated with antigens extracted chaotropically from Brucella ovis by potassium thiocyanate treatment were used to optimise a whole-cell, enzyme-linked immunosorbent assay (CELISA) and to monitor the temporal serological response of rams which had been challenged with infected semen by the intranasal or intrapreputial route. Three patterns of CELISA response were detected. Thirteen of 15 rams intranasally challenged did not respond serologically (pattern 1 or nil response). Only one of 15 rams in the intranasal group exhibited a rise and fall response with CELISA (pattern 2), while another showed a rise and surge response (pattern 3). The numbers of rams in the intrapreputial group which displayed a pattern 1 or 2 or 3 response were four, nine and two, respectively. No ram with a pattern 2 response excreted B ovis in the semen or showed any other evidence of infection, whereas rams with a pattern 3 response excreted B ovis in the semen and developed palpable lesions. Intrapreputially challenged rams that were CELISA-positive consistently mounted an antibody response against B ovis about two to four weeks earlier than intranasally challenged rams.

Macrophage activation and antitumor activity of a Brucella abortus ether extract, Bru-Pel.

Bru-Pel and Brucella abortus lipopolysaccharide (LPS) were tested for both macrophage activation and antitumor activity in an artificial metastasis model. Resting macrophages were rendered nonspecifically tumoricidal for MBL-2 lymphoblastic leukemia target cells by exposure to Bru-Pel at greater than or equal to 1 ng/ml of culture medium. B. abortus LPS failed to activate macrophages in vitro at all concentrations tested. Ip treatment of homozygous nude mice with Bru-Pel induced cytotoxic macrophages, indicating that Bru-Pel activated macrophages through a thymic-independent process. An artificial metastasis model was developed where single-cell suspensions of Madison 109 lung carcinoma were inoculated iv into syngeneic BALB/c mice. Bru-Pel, but not B. abortus LPS, strikingly inhibited tumor-colony formation in the lungs. Although Bru-Pel contains endotoxin, the data demonstrate that endotoxin is apparently not the active component by which Bru-Pel activates macrophages and enhances host resistance to cancer.

Immunization by an insoluble fraction extracted from Brucella melitensis: immunological and chemical characterization of the active substances.

A peptidoglycan-containing fraction called fraction P.I. (phenol insoluble), extracted from Brucella melitensis and previously described by some of us, had immunogenic and protective properties and did not produce any allergic reactions. Since it is well known that bacterial peptidoglycans studied so far have immunoadjuvant properties, the isolation of the active factor(s) of Brucella was undertaken. By successive enzymatic and chemical treatments, a new, much more purified fraction, called "4A" (approximately 5% of fraction P.I.), is obtained, retaining the same properties as P.I. and giving better protection against infection by Brucella. Immunogenicity, immunoadjuvant activity, allergizing capacity, and specific and nonspecific protective effects of fractions P.I. and 4A are compared. Chemically, fraction 4A is constituted by a lipoprotein covalently linked to peptidoglycan and by a few (lipo)proteins that could be solubilized by hot sodium dodecyl sulfate. Intrinsic properties of peptidoglycan could not be studied, but it does not seem to be essential for the activity. In conclusion, fractions P.I. and 4A are not agglutinogenic and, since fraction 4A induces better protection against infection by Brucella, it could advantageously replace fraction P.I. as a vaccine for humans.