Quorum-sensing and BvrR/BvrS regulation, the type IV secretion system, cyclic glucans, and BacA in the virulence of Brucella ovis: similarities to and differences from smooth brucellae.

Brucella ovis is a rough bacterium--lacking O-polysaccharide chains in the lipopolysaccharide--that is virulent in its natural host and whose virulence mechanisms remain almost unexplored. In a search for additional traits that distinguish B. ovis from smooth Brucella, which require O-polysaccharide chains for virulence, we have analyzed the significance in B. ovis of the main virulence factors described for smooth Brucella. Attempts to obtain strains of virulent B. ovis strain PA that are mutated in the BvrR/BvrS two-component regulatory system were unsuccessful, suggesting the requirement of that system for in vitro survival, while the inactivation of bacA--in contrast to the results seen with smooth Brucella--did not affect splenic colonization in mice or behavior in J774.A1 murine macrophages. Defects in the synthesis of cyclic ß-1,2 glucans reduced the uptake of B. ovis PA in macrophages and, although the intracellular multiplication rate was unaffected, led to attenuation in mice. Growth of strains with mutations in the type IV secretion system (encoded by the virB operon) and the quorum-sensing-related regulator VjbR was severely attenuated in the mouse model, and although the mutant strains internalized like the parental strain in J774.A1 murine macrophages, they were impaired for intracellular replication. As described for B. melitensis, VjbR regulates the transcription of the virB operon positively, and the N-dodecanoyl-dl-homoserine lactone (C(12)-HSL) autoinducer abrogates this effect. In contrast, no apparent VjbR-mediated regulation of the fliF flagellar gene was observed in B. ovis, probably due to the two deletions detected upstream of fliF. These results, together with others reported in the text, point to similarities between rough virulent B. ovis and smooth Brucella species as regards virulence but also reveal distinctive traits that could be related to the particular pathogenicity and host tropism characteristics of B. ovis.

Differences in the outer membrane-related properties of the six classical Brucella species.

Outer membrane-related properties (such as auto-agglutination and susceptibility to various compounds) of strains representative of the six classical species of the genus Brucella were assessed. The differences identified could not be fully explained based on the smooth or rough phenotype of the strain. Smooth strains of the closely related species Brucella melitensis and B. abortus exhibited different susceptibility patterns and the rough, virulent B. ovis and B. canis strains were equally or more resistant to conditions such as pH, non-immune serum, hydrogen peroxide and bactericidal cationic peptides than smooth strains. Such heterogeneity in outer membrane characteristics could account for differences in pathogenicity and host tropism.

Cholesterol, ganglioside GM1 and class A scavenger receptor contribute to infection by Brucella ovis and Brucella canis in murine macrophages.

The establishment of infection by Brucella ovis and Brucella canis in J774.A1 macrophages was found to be dependent upon cholesterol and ganglioside GM(1), two components of lipid rafts. This process also required a class A scavenger receptor of macrophages, and was not inhibited by smooth and rough lipopolysaccharides from Brucella spp. In response to infection, both bacteria induced a weak degree of macrophage activation. These results demonstrate that B. ovis and B. canis use cell surface receptors common to smooth Brucella spp. for macrophage infection, thus limiting macrophage activation and favouring intracellular multiplication and/or the survival of both bacteria.

Analysis of the occurrence and distribution of the Omp25/Omp31 family of surface proteins in the six classical Brucella species.

Members of the Omp25/Omp31 family of surface proteins were previously shown to participate in the virulence of some Brucella species and a different distribution of the seven proteins of this family among species could be related to the difference in pathogenicity and host preference they exhibit. Accordingly, in this work we have analyzed the expression of the genes coding for the Omp25/Omp31 family in the six classical Brucella species and a set of B. ovis mutant strains with each omp gene inactivated. Immunoblot of whole-cell lysates with antibodies raised against the purified recombinant outer membrane proteins (OMPs) did not show the simultaneous presence of the seven OMPs in any of the Brucella strains studied, but different Omp25/Omp31 profiles were detected, in our experimental conditions, between the Brucella strains representative of the six classical species. Transcripts for omp31, omp25 and omp25c were, in general, the most abundant of the family and some hits were found in B. ovis for a posttranscriptional regulation mechanism and for a compensatory mechanism increasing the synthesis of a protein to compensate for the absence of another one. Finally, the potential interest of Omp25c and Omp31b as subcellular vaccines, considering their occurrence in the Brucella strains studied and their antigenic relatedness with other proteins of the family, is discussed.

Importance of the Omp25/Omp31 family in the internalization and intracellular replication of virulent B. ovis in murine macrophages and HeLa cells.

The role of the outer membrane proteins of the Omp25/Omp31 family in invasiveness and intracellular survival of virulent B. ovis in phagocytes was analyzed. The absence of Omp25d or Omp22 in B. ovis abolished its invasive capacity in HeLa cells and reduced it in J774.A1 cells. Additionally, in J774.A1 cells, the Deltaomp25d mutant was unable to multiply, whereas the Deltaomp22 mutant was cleared at 24h post-infection. These findings demonstrate that Omp25d and Omp22 are essential for the invasion and survival of B. ovis inside host cells, and justify the strong attenuation in virulence of the Deltaomp25d and Deltaomp22 mutants.

Role of the Omp25/Omp31 family in outer membrane properties and virulence of Brucella ovis.

The genes coding for the five outer membrane proteins (OMPs) of the Omp25/Omp31 family expected to be located in the outer membrane (OM) of rough virulent Brucella ovis PA were inactivated to evaluate their role in virulence and OM properties. The OM properties of the mutant strains and of the mutants complemented with the corresponding wild-type genes were analyzed, in comparison with the parental strain and rough B. abortus RB51, in several tests: (i) binding of anti-Omp25 and anti-Omp31 monoclonal antibodies, (ii) autoagglutination of bacterial suspensions, and (iii) assessment of susceptibility to polymyxin B, sodium deoxycholate, hydrogen peroxide, and nonimmune ram serum. A tight balance of the members of the Omp25/Omp31 family was seen to be essential for the stability of the B. ovis OM, and important differences between the OMs of B. ovis PA and B. abortus RB51 rough strains were observed. Regarding virulence, the absence of Omp25d and Omp22 from the OM of B. ovis PA led to a drastic reduction in spleen colonization in mice. While the greater susceptibility of the Deltaomp22 mutant to nonimmune serum and its difficulty in surviving in the stationary phase might be on the basis of its dramatic attenuation, no defects in the OM able to explain the attenuation of the Deltaomp25d mutant were found, especially considering that the fully virulent Deltaomp25c mutant displayed more important OM defects. Accordingly, Omp25d, and perhaps Omp22, could be directly involved in the penetration and/or survival of B. ovis inside host cells. This aspect, together with the role of Omp25d and Omp22 in the virulence both of B. ovis in rams and of other Brucella species, should be thoroughly evaluated in future studies.