X. De Bolle

Identification of Brucella spp. genes involved in intracellular trafficking.

After uptake by host cells, the pathogen Brucella transits through early endosomes, evades phago–lysosome fusion and replicates in a compartment associated with the endoplasmic reticulum (ER). The molecular mechanisms underlying these processes are still poorly understood. To identify new bacterial factors involved in these processes, a library of 1800 Brucella melitensis 16M mini‐Tn5catkm mutants was screened for intracellular survival and multiplication in HeLa cells and J774A.1 macrophages. Thirteen mutants were identified as defective for their intracellular survival in both cell types. In 12 of them, the transposon had inserted in the virB operon, which encodes a type IV‐related secretion system. The preponderance of virB mutants demonstrates the importance of this secretion apparatus in the intracellular multiplication of B. melitensis. We also examined the intracellular fate of three virB mutants (virB2, virB4 and virB9) in HeLa cells by immunofluorescence. The three VirB proteins are not necessary for penetration and the inhibition of phago–lysosomal fusion within non‐professional phagocytes. Rather, the virB mutants are unable to reach the replicative niche and reside in a membrane‐bound vacuole expressing the late endosomal marker, LAMP1, and the sec61β protein from the ER membrane, proteins that are present in autophagic vesicles originating from the ER.

Identification and characterization of in vivo attenuated mutants of Brucella melitensis

Brucella melitensis 16M is a Gram‐negative α2‐proteobacterium responsible for abortion in goats and for Malta fever in humans. This facultative intracellular pathogen invades into and survives within both professional and non‐professional phagocytes. Signature‐tagged mutagenesis (STM) was used to identify genes required for the in vivo pathogenesis of Brucella. A library of transposon mutants was screened in a murine infection model. Out of 672 mutants screened, 20 were not recovered after a 5 day passage in BALB/c mice. The attenuation of 18 mutants was confirmed using an in vivo competition assay against the wild‐type strain. The 18 mutants were characterized further for their ability to replicate in murine macrophages and in HeLa cells. The sequences disrupted by the transposon in the mutants have homology to genes coding for proteins of different functional classes: transport, amino acid and DNA metabolism, transcriptional regulation, peptidoglycan synthesis, a chaperone‐like protein and proteins of unknown function. The mutants selected in this study provide new insights into the molecular basis of Brucella virulence.

Attenuated signature-tagged mutagenesis mutants of Brucella melitensis identified during the acute phase of infection in mice

ABSTRACT For this study, we screened 1,152 signature-tagged mutagenesis mutants of Brucella melitensis 16M in a mouse model of infection and found 36 of them to be attenuated in vivo. Molecular characterization of transposon insertion sites showed that for four mutants, the affected genes were only present in Rhizobiaceae. Another mutant contained a disruption in a gene homologous to mosA, which is involved in rhizopine biosynthesis in some strains of Rhizobium, suggesting that this sugar may be involved in Brucella pathogenicity. A mutant was disrupted in a gene homologous to fliF, a gene potentially coding for the MS ring, a basal component of the flagellar system. Surprisingly, a mutant was affected in the rpoA gene, coding for the essentialα -subunit of the RNA polymerase. This disruption leaves a partially functional protein, impaired for the activation of virB transcription, as demonstrated by the absence of induction of the virB promoter in the Tn5::rpoA background. The results presented here highlight the fact that the ability of Brucella to induce pathogenesis shares similarities with the molecular mechanisms used by both Rhizobium and Agrobacterium to colonize their hosts.

FtcR Is a New Master Regulator of the Flagellar System of Brucella melitensis 16M with Homologs in Rhizobiaceae

The flagellar regulon of Brucella melitensis 16M contains 31 genes clustered in three loci on the small chromosome. These genes encode a polar sheathed flagellum that is transiently expressed during vegetative growth and required for persistent infection in a mouse model. By following the expression of three flagellar genes (fliF, flgE, and fliC, corresponding to the MS ring, hook, and filament monomer, respectively), we identified a new regulator gene, ftcR (flagellar two-component regulator). Inactivation of ftcR led to a decrease in flagellar gene expression and to impaired Brucella virulence. FtcR has a two-component response regulator domain as well a DNA binding domain and is encoded in the first flagellar locus of B. melitensis. Both the ftcR sequence and its genomic context are conserved in other related alpha-proteobacteria. During vegetative growth in rich medium, ftcR expression showed a peak during the early exponential phase that paralleled fliF gene expression. VjbR, a quorum-sensing regulator of the LuxR family, was previously found to control fliF and flgE gene expression. Here, we provide some new elements suggesting that the effect of VjbR on these flagellar genes is mediated by FtcR. We found that ftcR expression is partially under the control of VjbR and that the expression in trans of ftcR in a vjbR mutant restored the production of the hook protein (FlgE). Finally, FtcR binds directly to the upstream region of the fliF gene. Therefore, our data support the role of FtcR as a flagellar master regulator in B. melitensis and perhaps in other related alpha-proteobacteria.

Brucella melitensis MucR, an Orthologue of Sinorhizobium meliloti MucR, Is Involved in Resistance to Oxidative, Detergent, and Saline Stresses and Cell Envelope Modifications

Brucella spp. and Sinorhizobium meliloti are alphaproteobacteria that share not only an intracellular lifestyle in their respective hosts, but also a crucial requirement for cell envelope components and their timely regulation for a successful infectious cycle. Here, we report the characterization of Brucella melitensis mucR, which encodes a zinc finger transcriptional regulator that has previously been shown to be involved in cellular and mouse infections at early time points. MucR modulates the surface properties of the bacteria and their resistance to environmental stresses (i.e., oxidative stress, cationic peptide, and detergents). We show that B. melitensis mucR is a functional orthologue of S. meliloti mucR, because it was able to restore the production of succinoglycan in an S. meliloti mucR mutant, as detected by calcofluor staining. Similar to S. meliloti MucR, B. melitensis MucR also represses its own transcription and flagellar gene expression via the flagellar master regulator ftcR. More surprisingly, we demonstrate that MucR regulates a lipid A core modification in B. melitensis. These changes could account for the attenuated virulence of a mucR mutant. These data reinforce the idea that there is a common conserved circuitry between plant symbionts and animal pathogens that regulates the relationship they have with their hosts.

Fun stories about Brucella: the "furtive nasty bug".

Although Brucella is responsible for one of the major worldwide zoonosis, our understanding of its pathogenesis remains in its infancy. In this paper, we summarize some of the research in progress in our laboratory that we think could contribute to a better understanding of the Brucella molecular virulence mechanisms and their regulation.

Intracellular rescuing of a B. melitensis 16M virB mutant by co-infection with a wild type strain

Brucella is a broad-range, facultative intracellular pathogen that can survive and replicate in an endoplasmic reticulum (ER)-derived replication niche by preventing fusion of its membrane-bound compartment with late endosomes and lysosomes. This vacuolar hijacking was demonstrated to be dependent on the type IV secretion system VirB but no secreted effectors have been identified yet. A virB mutant is unable to reach its ER-derived replicative niche and does not multiply intracellularly. In this paper, we showed that, by co-infecting bovine macrophages or HeLa cells with the wild type (WT) strain of Brucella melitensis 16M and a deletion mutant of the complete virB operon, the replication of DeltavirB is rescued in almost 20% of the co-infected cells. Furthermore, we demonstrated that co-infections with the WT strains of Brucella abortus or Brucella suis were equally able to rescue the replication of the B. melitensis DeltavirB mutant. By contrast, no rescue was observed when the WT strain was given 1h before or after the infection with the DeltavirB mutant. Finally, vacuoles containing the rescued DeltavirB mutant were shown to exclude the LAMP-1 marker in a way similar to the WT containing vacuoles.

Purification, refolding and characterization of the trimeric Omp2a outer membrane porin from Brucella melitensis.

Brucella melitensis is a gram-negative bacteria known to cause brucellosis and to produce severe infections in humans. Whilst brucellas outer membrane proteins have been extensively studied due to their potential role as antigens or virulence factors, their function is still poorly understood at the structural level, as the 3D structure of Brucella β-barrel membrane proteins are still unknown. In this context, the B. melitensis trimeric Omp2a porin has been overexpressed and refolded in n-dodecyl-β-d-maltopyranoside. We here show that this refolding process is insensitive to urea but is temperature- and ionic strength-dependent. Reassembled species were characterized by fluorescence, size-exclusion chromatography and circular dichroism. A refolding mechanism is proposed, suggesting that Omp2a first refolds under a monomeric form and then self-associates into a trimeric state. This first complete in vitro refolding of a membrane protein from B. melitensis shall eventually lead to functional and 3D structure determination.

Brucella central carbon metabolism: an update

Abstract The brucellae are facultative intracellular pathogens causing brucellosis, an important zoonosis. Here, we review the nutritional, genetic, proteomic and transcriptomic studies on Brucella carbon uptake and central metabolism, information that is needed for a better understanding of Brucella virulence. There is no uniform picture across species but the studies suggest primary and/or secondary transporters for unknown carbohydrates, lactate, glycerol phosphate, erythritol, xylose, ribose, glucose and glucose/galactose, and routes for their incorporation to central metabolism, including an erythritol pathway feeding the pentose phosphate cycle. Significantly, all brucellae lack phosphoenolpyruvate synthase and phosphofructokinase genes, which confirms previous evidence on glycolysis absence, but carry all Entner–Doudoroff (ED) pathway and Krebs cycle (and glyoxylate pathway) genes. However, glucose catabolism proceeds through the pentose phosphate cycle in the classical species, and the ED pathway operates in some rodent-associated brucellae, suggesting an ancestral character for this pathway in this group. Gluconeogenesis is functional but does not rely exclusively on classical fructose bisphosphatases. Evidence obtained using infection models is fragmentary but suggests the combined or sequential use of hexoses/pentoses, amino acids and gluconeogenic substrates. We also discuss the role of the phosphotransferase system, stringent reponse, quorum sensing, BvrR/S and sRNAs in metabolism control, an essential aspect of the life style of facultative intracellular parasites.