Véronique Jubier-Maurin

Major Outer Membrane Protein Omp25 of Brucella suis Is Involved in Inhibition of Tumor Necrosis Factor Alpha Production during Infection of Human Macrophages

ABSTRACT Brucella spp. can establish themselves and cause disease in humans and animals. The mechanisms by whichBrucella spp. evade the antibacterial defenses of their host, however, remain largely unknown. We have previously reported that live brucellae failed to induce tumor necrosis factor alpha (TNF-α) production upon human macrophage infection. This inhibition is associated with a nonidentified protein that is released into culture medium. Outer membrane proteins (OMPs) of gram-negative bacteria have been shown to modulate macrophage functions, including cytokine production. Thus, we have analyzed the effects of two major OMPs (Omp25 and Omp31) of Brucella suis 1330 (wild-type [WT] B. suis) on TNF-α production. For this purpose, omp25and omp31 null mutants of B. suis(Δomp25 B. suis and Δomp31 B. suis, respectively) were constructed and analyzed for the ability to activate human macrophages to secrete TNF-α. We showed that, in contrast to WTB. suis or Δomp31 B. suis, Δomp25 B. suis induced TNF-α production when phagocytosed by human macrophages. The complementation of Δomp25 B. suis with WT omp25 (Δomp25-omp25 B. suis mutant) significantly reversed this effect: Δomp25-omp25 B. suis-infected macrophages secreted significantly less TNF-α than did macrophages infected with the Δomp25 B. suismutant. Furthermore, pretreatment of WT B. suis with an anti-Omp25 monoclonal antibody directed against an epitope exposed at the surface of the bacteria resulted in substancial TNF-α production during macrophage infection. These observations demonstrated that Omp25 of B. suis is involved in the negative regulation of TNF-α production upon infection of human macrophages.

Requirement of norD for Brucella suis Virulence in a Murine Model of In Vitro and In Vivo Infection

ABSTRACT A mutant of Brucella suis bearing a Tn5 insertion in norD, the last gene of the operon norEFCBQD, encoding nitric oxide reductase, was unable to survive under anaerobic denitrifying conditions. The norD strain exhibited attenuated multiplication within nitric oxide-producing murine macrophages and rapid elimination in mice, hence demonstrating that norD is essential for Brucella virulence.

The intramacrophagic environment of Brucella suis and bacterial response

Phagocytes have developed various antimicrobial defense mechanisms to eliminate pathogens. They comprise the oxidative burst, acidification of phagosomes, or fusion of phagosomes with lysosomes. Facultative intracellular bacteria, in return, have developed strategies counteracting the host cell defense, resulting in intramacrophagic survival. Until lately, only very little was known about the phagosomal compartment containing Brucella spp., the environmental conditions the bacteria encounter, and the pathogens stress response. Recently, we have determined that the phagosomes acidify rapidly to a pH of 4.0-4.5 following infection, but this early acidification is crucial for intracellular replication as neutralization results in bacterial elimination. A vacuolar proton-ATPase is responsible for this phenomenon that is not linked to phagosome-lysosome fusion. On the contrary, in vitro reconstitution assays revealed association only between phagosomes containing killed B. suis and lysosomes, describing the absence of phagolysosome fusion due to specific recognition inhibition for live bacteria. Further evidence for the necessity of an intact, acidic phagosome as a predominant niche of brucellae in macrophages was obtained with a strain of B. suis secreting listeriolysin. It partially disrupts the phagosomal membranes and fails to multiply intracellularly. How does B. suis adapt to this environment? We have identified and studied a series of genes that are involved in this process of adaptation. The bacterial heat shock protein and chaperone DnaK is induced in phagocytes and it is essential for intracellular multiplication. A low-level, constitutive expression of dnaK following promoter exchange does not restore intramacrophagic survival. Another chaperone and heat shock protein, ClpB, belonging to the family of ClpATPases, is important for the resistance of B. suis to several in vitro stresses, but does not contribute to intramacrophagic survival of the pathogen. Additional bacterial genes specifically induced within the phagocyte were identified by an intramacrophagic screen of random promoter fusions to the reporter gene gfp. A large majority of these genes are encoding proteins involved in transport of nutrients (sugars, amino acids), or cofactors, such as nickel. Analysis of the intracellular gene activation reveals that low oxygen tension is encountered by B. suis. Altogether, these results suggest three major stress conditions encountered by brucellae in the phagosome: acid stress, starvation and low oxygen tension.

Identification of the nik Gene Cluster of Brucella suis: Regulation and Contribution to Urease Activity

Analysis of a Brucella suis 1330 gene fused to a gfp reporter, and identified as being induced in J774 murine macrophage-like cells, allowed the isolation of a gene homologous to nikA, the first gene of the Escherichia coli operon encoding the specific transport system for nickel. DNA sequence analysis of the corresponding B. suis nik locus showed that it was highly similar to that of E. coli except for localization of the nikR regulatory gene, which lies upstream from the structural nikABCDE genes and in the opposite orientation. Protein sequence comparisons suggested that the deduced nikABCDE gene products belong to a periplasmic binding protein-dependent transport system. The nikA promoter-gfp fusion was activated in vitro by low oxygen tension and metal ion deficiency and was repressed by NiCl(2) excess. Insertional inactivation of nikA strongly reduced the activity of the nickel metalloenzyme urease, which was restored by addition of a nickel excess. Moreover, the nikA mutant of B. suis was functionally complemented with the E. coli nik gene cluster, leading to the recovery of urease activity. Reciprocally, an E. coli strain harboring a deleted nik operon recovered hydrogenase activity by heterologous complementation with the B. suis nik locus. Taking into account these results, we propose that the nik locus of B. suis encodes a nickel transport system. The results further suggest that nickel could enter B. suis via other transport systems. Intracellular growth rates of the B. suis wild-type and nikA mutant strains in human monocytes were similar, indicating that nikA was not essential for this step of infection. We discuss a possible role of nickel transport in maintaining enzymatic activities which could be crucial for survival of the bacteria under the environmental conditions encountered within the host.

Quantitative analysis of the intramacrophagic Brucella suis proteome reveals metabolic adaptation to late stage of cellular infection

A 2‐D DIGE approach allowed the characterization of the intramacrophagic proteome of the intracellular pathogen Brucella suis at the late stage of in vitro infection by efficient discrimination between bacterial and host cell proteins. Using a subtraction model, a total of 168 proteins showing altered concentrations in comparison with extracellularly grown, stationary‐phase bacteria were identified. The majority of the 44 proteins significantly regulated at this stage of infection were involved in bacterial metabolism and 40% were present in lowered concentrations, supporting the hypothesis of an adaptive response by quantitative reduction of processes participating in energy, protein, and nucleic acid metabolism. In the future, the 2‐D DIGE‐based approach will permit to decipher specifically and quantitatively the intracellular proteomes of various pathogens during adaptation to their specific host cell environments.

Differential use of the two high-oxygen-affinity terminal oxidases of Brucella suis for in vitro and intramacrophagic multiplication.

ABSTRACT Expression of the high-oxygen-affinity cytochrome cbb3 and cytochrome bd ubiquinol oxidases of Brucella suis was studied in vitro and in the intramacrophagic niche, which was previously proposed to be oxygen limited. The cytochrome cbb3 oxidase was exclusively expressed in vitro, whereas the cytochrome bd oxidase was preferentially used inside macrophages and contributed to intracellular bacterial replication.

Different Roles of the Two High-Oxygen-Affinity Terminal Oxidases of Brucella suis: Cytochrome c Oxidase, but Not Ubiquinol Oxidase, Is Required for Persistence in Mice

ABSTRACT The survival of Brucella suis mutant strains in mice demonstrated different roles of the two high-oxygen-affinity terminal oxidases. The cbb3-type cytochrome c oxidase was essential for chronic infection in oxygen-deficient organs. Lack of the cytochrome bd ubiquinol oxidase led to hypervirulence of bacteria, which could rely on nitrite accumulation inhibiting the inducible nitric oxide synthase of the host.

Proteomic analysis of Brucella suis under oxygen deficiency reveals flexibility in adaptive expression of various pathways

Low oxygen tension was proposed to be one of the environmental parameters characteristic of the patho‐physiological conditions of natural infections by Brucella suis. We previously showed that various respiratory pathways may be used by B. suis in response to microaerobiosis and anaerobiosis. Here, we compare the whole proteome of B. suis exposed to such low‐oxygenated conditions to that obtained from bacteria grown under ambient air using 2‐D DIGE. Data showed that the reduction of basal metabolism was in line with low or absence of growth of B. suis. Under both microaerobiosis and anaerobiosis, glycolysis and denitrification were favored. In addition, fatty acid oxidation and possibly citrate fermentation could also contribute to energy production sufficient for survival under anaerobiosis. When oxygen availability changed and became limiting, basic metabolic processes were still functional and variability of respiratory pathways was observed to a degree unexpected for a strictly aerobic microorganism. This highly flexible respiration probably constitutes an advantage for the survival of Brucella under the restricted oxygenation conditions encountered within host tissue.

RegA, the Regulator of the Two-Component System RegB/RegA of Brucella suis, Is a Controller of Both Oxidative Respiration and Denitrification Required for Chronic Infection in Mice

ABSTRACT Adaptation to oxygen deficiency is essential for virulence and persistence of Brucella inside the host. The flexibility of this bacterium with respect to oxygen depletion is remarkable, since Brucella suis can use an oxygen-dependent transcriptional regulator of the FnrN family, two high-oxygen-affinity terminal oxidases, and a complete denitrification pathway to resist various conditions of oxygen deficiency. Moreover, our previous results suggested that oxidative respiration and denitrification can be simultaneously used by B. suis under microaerobiosis. The requirement of a functional cytochrome bd ubiquinol oxidase for nitrite reductase expression evidenced the linkage of these two pathways, and the central role of the two-component system RegB/RegA in the coordinated control of both respiratory systems was demonstrated. We propose a scheme for global regulation of B. suis respiratory pathways by the transcriptional regulator RegA, which postulates a role for the cytochrome bd ubiquinol oxidase in redox signal transmission to the histidine sensor kinase RegB. More importantly, RegA was found to be essential for B. suis persistence in vivo within oxygen-limited target organs. It is conceivable that RegA acts as a controller of numerous systems involved in the establishment of the persistent state, characteristic of chronic infections by Brucella.

Quantitative analysis of the Brucella suis proteome reveals metabolic adaptation to long-term nutrient starvation

BackgroundDuring the infection process, bacteria are confronted with various stress factors including nutrient starvation. In an in vitro model, adaptation strategies of nutrient-starved brucellae, which are facultative intracellular pathogens capable of long-term persistence, were determined.ResultsLong-term nutrient starvation in a medium devoid of carbon and nitrogen sources resulted in a rapid decline in viability of Brucella suis during the first three weeks, followed by stabilization of the number of viable bacteria for a period of at least three weeks thereafter. A 2D-Difference Gel Electrophoresis (DIGE) approach allowed the characterization of the bacterial proteome under these conditions. A total of 30 proteins showing altered concentrations in comparison with bacteria grown to early stationary phase in rich medium were identified. More than half of the 27 significantly regulated proteins were involved in bacterial metabolism with a marked reduction of the concentrations of enzymes participating in amino acid and nucleic acid biosynthesis. A total of 70% of the significantly regulated proteins showed an increased expression, including proteins involved in the adaptation to harsh conditions, in regulation, and in transport.ConclusionsThe adaptive response of Brucella suis most likely contributes to the long-term survival of the pathogen under starvation conditions, and may play a key role in persistence.