If You're Not Confused, You're Not Paying Attention: Ochrobactrum Is Not Brucella

Bacteria of the genus Brucella are facultative intracellular parasites that cause brucellosis, a severe animal and human disease. Recently, a group of taxonomists merged the brucellae with the primarily free-living, phylogenetically related Ochrobactrum spp. in the genus Brucella. This change, founded only on global genomic analysis and the fortuitous isolation of some opportunistic Ochrobactrum spp. from medically compromised patients, has been automatically included in culture collections and databases. We argue that clinical and environmental microbiologists should not accept this nomenclature, and we advise against its use because (i) it was presented without in-depth phylogenetic analyses and did not consider alternative taxonomic solutions; (ii) it was launched without the input of experts in brucellosis or Ochrobactrum; (iii) it applies a non-consensus genus concept that disregards taxonomically relevant differences in structure, physiology, population structure, core-pangenome assemblies, genome structure, genomic traits, clinical features, treatment, prevention, diagnosis, genus description rules, and, above all, pathogenicity; and (iv) placing these two bacterial groups in the same genus creates risks for veterinarians, medical doctors, clinical laboratories, health authorities, and legislators who deal with brucellosis, a disease that is particularly relevant in low- and middle-income countries. Based on all this information, we urge microbiologists, bacterial collections, genomic databases, journals, and public health boards to keep the Brucella and Ochrobactrum genera separate to avoid further bewilderment and harm.

The microbiome of the ice-capped Cayambe Volcanic Complex in Ecuador

A major challenge in microbial ecology is to understand the principles and processes by which microbes associate and interact in community assemblages. Microbial communities in mountain glaciers are unique as first colonizers and nutrient enrichment drivers for downstream ecosystems. However, mountain glaciers have been distinctively sensitive to climate perturbations and have suffered a severe retreat over the past 40  years, compelling us to understand glacier ecosystems before their disappearance. This is the first study in an Andean glacier in Ecuador offering insights into the relationship of physicochemical variables and altitude on the diversity and structure of bacterial communities. Our study covered extreme Andean altitudes at the Cayambe Volcanic Complex, from 4,783 to 5,583 masl. Glacier soil and ice samples were used as the source for 16S rRNA gene amplicon libraries. We found (1) effects of altitude on diversity and community structure, (2) the presence of few significantly correlated nutrients to community structure, (3) sharp differences between glacier soil and glacier ice in diversity and community structure, where, as quantified by the Shannon γ-diversity distribution, the meta-community in glacier soil showed more diversity than in glacier ice; this pattern was related to the higher variability of the physicochemical distribution of variables in the former substrate, and (4) significantly abundant genera associated with either high or low altitudes that could serve as biomarkers for studies on climate change. Our results provide the first assessment of these unexplored communities, before their potential disappearance due to glacier retreat and climate change.

Polymorphisms in Brucella Carbonic Anhydrase II Mediate CO2 Dependence and Fitness in vivo

Some Brucella isolates are known to require an increased concentration of CO₂ for growth, especially in the case of primary cultures obtained directly from infected animals. Moreover, the different Brucella species and biovars show a characteristic pattern of CO₂ requirement, and this trait has been included among the routine typing tests used for species and biovar differentiation. By comparing the differences in gene content among different CO₂-dependent and CO₂-independent Brucella strains, we have confirmed that carbonic anhydrase (CA) II is the enzyme responsible for this phenotype in all the Brucella strains tested. Brucella species contain two CAs of the β family, CA I and CA II; genetic polymorphisms exist for both of them in different isolates, but only those putatively affecting the activity of CA II correlate with the CO₂ requirement of the corresponding isolate. Analysis of these polymorphisms does not allow the determination of CA I functionality, while the polymorphisms in CA II consist of small deletions that cause a frameshift that changes the C-terminus of the protein, probably affecting its dimerization status, essential for the activity. CO₂-independent mutants arise easily in vitro, although with a low frequency ranging from 10^–6 to 10^–10 depending on the strain. These mutants carry compensatory mutations that produce a full-length CA II. At the same time, no change was observed in the sequence coding for CA I. A competitive index assay designed to evaluate the fitness of a CO₂-dependent strain compared to its corresponding CO₂-independent strain revealed that while there is no significant difference when the bacteria are grown in culture plates, growth in vivo in a mouse model of infection provides a significant advantage to the CO₂-dependent strain. This could explain why some Brucella isolates are CO₂ dependent in primary isolation. The polymorphism described here also allows the in silico determination of the CO₂ requirement status of any Brucella strain.

#EUROmicroMOOC: using Twitter to share trends in Microbiology worldwide

Twitter is one of the most popular social media networks that, in recent years, has been increasingly used by researchers as a platform to share science and discuss ongoing work. Despite its popularity, Twitter is not commonly used as a medium to teach science. Here, we summarize the results of #EUROmicroMOOC: the first worldwide Microbiology Massive Open Online Course taught in English using Twitter. Content analytics indicated that more than 3 million users saw posts with the hashtag #EUROmicroMOOC, which resulted in over 42 million Twitter impressions worldwide. These analyses demonstrate that free Microbiology MOOCs shared on Twitter are valuable educational tools that reach broad audiences throughout the world. We also describe our experience teaching an entire Microbiology course using Twitter and provide recommendations when using social media to communicate science to a broad audience.

A Functional oriT in the Ptw Plasmid of Burkholderia cenocepacia Can Be Recognized by the R388 Relaxase TrwC

Burkholderia cenocepacia is both a plant pathogen and the cause of serious opportunistic infections, particularly in cystic fibrosis patients. B. cenocepacia K56-2 harbors a native plasmid named Ptw for its involvement in the Plant Tissue Watersoaking phenotype. Ptw has also been reported to be important for survival in human cells. Interestingly, the presence of PtwC, a homolog of the conjugative relaxase TrwC of plasmid R388, suggests a possible function for Ptw in conjugative DNA transfer. The ptw region includes Type IV Secretion System genes related to those of the F plasmid. However, genes in the adjacent region shared stronger homology with the R388 genes involved in conjugative DNA metabolism. This region included the putative relaxase ptwC, a putative coupling protein and accessory nicking protein, and a DNA segment with high number of inverted repeats and elevated AT content, suggesting a possible oriT. Although we were unable to detect conjugative transfer of the Ptw resident plasmid, we detected conjugal mobilization of a co-resident plasmid containing the ptw region homologous to R388, demonstrating the cloned ptw region contains an oriT. A similar plasmid lacking ptwC could not be mobilized, suggesting that the putative relaxase PtwC must act in cis on its oriT. Remarkably, we also detected mobilization of a plasmid containing the Ptw oriT by the R388 relaxase TrwC, yet we could not detect PtwC-mediated mobilization of an R388 oriT-containing plasmid. Our data unambiguously show that the Ptw plasmid harbors DNA transfer functions, and suggests the Ptw plasmid may play a dual role in horizontal DNA transfer and eukaryotic infection.

Evolutionary diversification and characterization of the eubacterial gene family encoding DXR type II, an alternative isoprenoid biosynthetic enzyme

BACKGROUND

Isoprenoids constitute a vast family of natural compounds performing diverse and essential functions in all domains of life. In most eubacteria, isoprenoids are synthesized through the methylerythritol 4-phosphate (MEP) pathway. The production of MEP is usually catalyzed by deoxyxylulose 5-phosphate reductoisomerase (DXR-I) but a few organisms use an alternative DXR-like enzyme (DXR-II).

RESULTS

Searches through 1498 bacterial complete proteomes detected 130 sequences with similarity to DXR-II. Phylogenetic analysis identified three well-resolved clades: the DXR-II family (clustering 53 sequences including eleven experimentally verified as functional enzymes able to produce MEP), and two previously uncharacterized NAD(P)-dependent oxidoreductase families (designated DLO1 and DLO2 for DXR-II-like oxidoreductases 1 and 2). Our analyses identified amino acid changes critical for the acquisition of DXR-II biochemical function through type-I functional divergence, two of them mapping onto key residues for DXR-II activity. DXR-II showed a markedly discontinuous distribution, which was verified at several levels: taxonomic (being predominantly found in Alphaproteobacteria and Firmicutes), metabolic (being mostly found in bacteria with complete functional MEP pathways with or without DXR-I), and phenotypic (as no biological/phenotypic property was found to be preferentially distributed among DXR-II-containing strains, apart from pathogenicity in animals). By performing a thorough comparative sequence analysis of GC content, 3:1 dinucleotide frequencies, codon usage and codon adaptation indexes (CAI) between DXR-II sequences and their corresponding genomes, we examined the role of horizontal gene transfer (HGT), as opposed to an scenario of massive gene loss, in the evolutionary origin and diversification of the DXR-II subfamily in bacteria.

CONCLUSIONS

Our analyses support a single origin of the DXR-II family through functional divergence, in which constitutes an exceptional model of acquisition and maintenance of redundant gene functions between non-homologous genes as a result of convergent evolution. Subsequently, although old episodic events of HGT could not be excluded, the results supported a prevalent role of gene loss in explaining the distribution of DXR-II in specific pathogenic eubacteria. Our results highlight the importance of the functional characterization of evolutionary shortcuts in isoprenoid biosynthesis for screening specific antibacterial drugs and for regulating the production of isoprenoids of human interest.

Brucella abortus ure2 region contains an acid-activated urea transporter and a nickel transport system

BACKGROUND

Urease is a virulence factor that plays a role in the resistance of Brucella to low pH conditions, both in vivo and in vitro. Brucella contains two separate urease gene clusters, ure1 and ure2. Although only ure1 codes for an active urease, ure2 is also transcribed, but its contribution to Brucella biology is unknown.

RESULTS

Re-examination of the ure2 locus showed that the operon includes five genes downstream of ureABCEFGDT that are orthologs to a nikKMLQO cluster encoding an ECF-type transport system for nickel. ureT and nikO mutants were constructed and analyzed for urease activity and acid resistance. A non-polar ureT mutant was unaffected in urease activity at neutral pH but showed a significantly decreased activity at acidic pH. It also showed a decreased survival rate to pH 2 at low concentration of urea when compared to the wild type. The nikO mutant had decreased urease activity and acid resistance at all urea concentrations tested, and this phenotype could be reverted by the addition of nickel to the growth medium.

CONCLUSIONS

Based on these results, we concluded that the operon ure2 codes for an acid-activated urea transporter and a nickel transporter necessary for the maximal activity of the urease whose structural subunits are encoded exclusively by the genes in the ure1 operon.

Characterization of the urease operon of Brucella abortus and assessment of its role in virulence of the bacterium

Most members of the genus Brucella show strong urease activity. However, the role of this enzyme in the pathogenesis of Brucella infections is poorly understood. We isolated several Tn5 insertion mutants deficient in urease activity from Brucella abortus strain 2308. The mutations of most of these mutants mapped to a 5.7-kbp DNA region essential for urease activity. Sequencing of this region, designated ure1, revealed the presence of seven open reading frames corresponding to the urease structural proteins (UreA, UreB, and UreC) and the accessory proteins (UreD, UreE, UreF, and UreG). In addition to the urease genes, another gene (cobT) was identified, and inactivation of this gene affected urease activity in Brucella. Subsequent analysis of the previously described sequences of the genomes of Brucella spp. revealed the presence of a second urease cluster, ure2, in all them. The ure2 locus was apparently inactive in B. abortus 2308. Urease-deficient mutants were used to evaluate the role of urease in Brucella pathogenesis. The urease-producing strains were found to be resistant in vitro to strong acid conditions in the presence of urea, while urease-negative mutants were susceptible to acid treatment. Similarly, the urease-negative mutants were killed more efficiently than the urease-producing strains during transit through the stomach. These results suggested that urease protects brucellae during their passage through the stomach when the bacteria are acquired by the oral route, which is the major route of infection in human brucellosis.

Functional interactions between type IV secretion systems involved in DNA transfer and virulence

This paper reports an analysis of the functional interactions between type IV secretion systems (T4SS) that are part of the conjugative machinery for horizontal DNA transfer (cT4SS), and T4SS involved in bacterial pathogenicity (pT4SS). The authors' previous work showed that a conjugative coupling protein (T4CP) interacts with the VirB10-type component of the T4SS in order to recruit the protein-DNA complex to the transporter for conjugative DNA transfer. This study now shows by two-hybrid analysis that conjugative T4CPs also interact with the VirB10 element of the pT4SS of Agrobacterium tumefaciens (At), Bartonella tribocorum (Bt) and Brucella suis (Bs). Moreover, the VirB10 component of a cT4SS (protein TrwE of plasmid R388) could be partially substituted by that of a pT4SS (protein TrwE of Bt) for conjugation. This result opens the way for the construction of hybrid T4SS that deliver DNA into animal cells. Interestingly, in the presence of part of the Bs T4SS the R388 T4SS protein levels were decreased and R388 conjugation was strongly inhibited. Complementation assays between the Trw systems of R388 and Bt showed that only individual components from the so-called 'core complex' could be exchanged, supporting the concept that this core is the common scaffold for the transport apparatus while the other 'peripheral components' are largely system-specific.

Generation of the Brucella melitensis ORFeome version 1.1

The bacteria of the Brucella genus are responsible for a worldwide zoonosis called brucellosis. They belong to the alpha-proteobacteria group, as many other bacteria that live in close association with a eukaryotic host. Importantly, the Brucellae are mainly intracellular pathogens, and the molecular mechanisms of their virulence are still poorly understood. Using the complete genome sequence of Brucella melitensis, we generated a database of protein-coding open reading frames (ORFs) and constructed an ORFeome library of 3091 Gateway Entry clones, each containing a defined ORF. This first version of the Brucella ORFeome (v1.1) provides the coding sequences in a user-friendly format amenable to high-throughput functional genomic and proteomic experiments, as the ORFs are conveniently transferable from the Entry clones to various Expression vectors by recombinational cloning. The cloning of the Brucella ORFeome v1.1 should help to provide a better understanding of the molecular mechanisms of virulence, including the identification of bacterial protein-protein interactions, but also interactions between bacterial effectors and their host's targets.

Functional expression and characterization of EryA, the erythritol kinase of Brucella abortus, and enzymatic synthesis of L-erythritol-4-phosphate

The eryA gene of the bacterial pathogen Brucella abortus has been functionally expressed in Escherichia coli. The resultant EryA was shown to catalyze the ATP-dependent conversion of erythritol to L-erythritol-4-phosphate (L-E4P). The steady state kinetic parameters of this reaction were determined and the enzyme was used to prepare L-E4P which was shown to be a weak inhibitor of 2-C-methyl-D-erythritol-4-phosphate cytidyltransferase (YgbP).

Brucella abortus strain 2308 produces brucebactin, a highly efficient catecholic siderophore

Brucella abortus is known to produce 2,3-dihydroxybenzoate (2,3-DHBA) and to use this catechol as a siderophore to grow under iron-limited conditions. In this study a mutant (BAM41) is described that is deficient in siderophore production by insertion of Tn5 in the virulent B. abortus strain 2308. This mutant was unable to grow on iron-deprived medium and its growth could not be restored by addition of 2,3-DHBA. Production of catecholic compounds by both the Brucella mutant and parental strains under iron-deprivation conditions was assayed by TLC. Two catecholic substances were identified in the supernatant of the parental strain 2308. The faster migrating spot showed the same retention factor (R(f)) as that of purified 2,3-DHBA. The mutant BAM41 overproduced 2,3-DHBA, but failed to form the slower migrating catechol. This defect could only be complemented by the addition of the slow-migrating catechol from strain 2308. The genomic region containing Tn5 in BAM41 was cloned and the position of the transposon was determined by nucleotide sequencing. The sequence revealed that the insertion had occurred at a gene with homology to Escherichia coli entF, a locus involved in the late steps of the biosynthesis of the complex catecholic siderophore enterobactin. Intracellular survival and growth rates of the B. abortus wild-type and entF mutant strains in mouse-derived J774 macrophages were similar, indicating that production of this siderophore was not essential in this model of infection. It is concluded that B. abortus synthesizes a previously unknown and highly efficient catecholic siderophore, different from 2,3-DHBA, for which the name brucebactin is proposed.

Characterization of IS666, a newly described insertion element of Mycobacterium avium

The insertion sequence IS666 was isolated from Mycobacterium avium strain 101. IS666 is a 1474 bp insertion sequence belonging to the IS256 family, that includes IS6120 from Mycobacterium smegmatis, IS1166 and IS1295 from Rhodococcus sp. IGTS8, IST2 from Thiobacillus ferrooxidans, IS256 from Staphylococcus aureus, and ISRm3 from Rhizobium meliloti. IS666 has 24 bp imperfect inverted repeats that fit the consensus described for the family, and generates 9 bp duplications upon insertion into the host DNA with no apparent specificity in the target sequence. In contrast with its two closest homologues, IS1166 and IS6120, IS666 contains a single ORF that would codify a transposase of 434 aa. IS666 is restricted to M. avium, where it is present in 21% of the isolates in a number ranging between 1 to 7 copies.

Characterization and expression of secA in Mycobacterium avium

Mycobacterium avium is both a pathogen that infects several hosts such as humans, pigs, and birds, as well as a microorganism that is encountered in environmental sources (soil and water). Protein secretion by the bacterium is likely to influence its ability to overcome adverse and competitive conditions both within or outside the host. Using a combination of cloning and information available in the databank, we characterized the secA gene from M. avium, encoding for a major preprotein translocase subunit associated with the secretion system of prokaryotics. In addition, we cloned the secA promoter sequence in a reporter construct upstream of a promoterless gfp. It was determined that the secA of M. avium shares large homology with the secA of Mycobacterium tuberculosis but not with secA of Mycobacterium leprae. secA expression was determined to be greater at logarithmic growth phase although it was also expressed at low levels during the stationary phase. secA expression was also observed when the bacteria were incubated in water as well as within human monocyte-derived macrophages and in conditions that are associated with biofilm formation. Future evaluation of the sec pathway in M. avium might provide important information about secreted proteins that are required for survival in different environments.

Mycobacterium avium invades the intestinal mucosa primarily by interacting with enterocytes

Previous studies have demonstrated that Mycobacterium avium can invade intestinal epithelial cells both in vitro and in vivo. When given to mice orally, M. avium preferentially interacts with the intestinal mucosa at the terminal ileum. We evaluated the mechanism(s) of M. avium binding and invasion of the intestinal mucosa using three different systems: (i) electron microscopy following administration of M. avium into an intestinal loop in mice, (ii) quantitative comparison of the bacterial load in Peyer's patch areas of the terminal ileum versus areas that do not contain Peyer's patches, and (iii) investigation of the ability of M. avium to cause disseminated infection following oral administration using B-cell-deficient mice, lacking Peyer's patches, in comparison with C57BL/6 black mice. By all approaches, M. avium was found to invade the intestinal mucosa by interacting primarily with enterocytes and not with M cells.

Cellular and molecular mechanisms of internalization of mycobacteria by host cells

Mycobacteria are intracellular pathogens capable of invading mononuclear phagocytes, mucosal epithelial cells (including M cells) and Schwann cells. To enter cells, mycobacteria have been shown to interact with several molecules on macrophage and epithelial cell surfaces. This suggests adaptation to the host environment. In this review we address the strategies used by pathogenic mycobacteria to gain access to the intracellular environment.

Mycobacterium avium enters intestinal epithelial cells through the apical membrane, but not by the basolateral surface, activates small GTPase Rho and, once within epithelial cells, expresses an invasive phenotype

Mycobacterium avium is a common pathogen in AIDS patients that is primarily (but not exclusively) acquired through the gastrointestinal tract, leading to the development of bacteraemia and disseminated disease. To cause infection through the gut, binding and invasion of the intestinal epithelial barrier are required. To characterize this process further, we determined the cell surface(s) (basolateral vs. apical membrane) that M. avium interacts with in intestinal mucosal cells in vitro. The level of binding and invasion of both HT-29 and Caco-2 intestinal cell monolayers by M. avium were similar when the assay was performed with control medium in the presence of Ca2+ (when only the apical surface was exposed), with Ca2+-depleted medium or with Ca2+-depleted medium + 1 mM EGTA (exposure of both apical and basolateral membranes), suggesting that the bacterium enters the apical surface of the epithelial lining. These observations were confirmed by assays in a transwell system and by using fluorescent microscopy. Real-time video microscopy showed that M. avium entry was not associated with membrane ruffling and the use of pharmacological inhibitors of the small GTPases demonstrated that M. avium invasion is dependent on the activation of the small GTPases Rho, but not on Rac or Cdc42. Passage of M. avium through HT-29 cells led to a phenotypic change (intracellular growth; IG) that was associated with a significantly greater (between five- and ninefold) ability to bind to and invade new monolayers of epithelial cells or macrophages when compared with the invasion by M. avium grown on agar (extracellular growth; EG). IG phenotype invasion of HT-29 cells also takes place only by the apical surface. M. avium enters intestinal epithelial cells by the apical surface and, once within the cells, changes phenotype, becoming more invasive towards both macrophages and other epithelial cells.

The genes for erythritol catabolism are organized as an inducible operon in Brucella abortus

Erythritol utilization is a characteristic of pathogenic Brucella abortus strains. The attenuated vaccine strain B19 is the only Brucella strain that is inhibited by erythritol, so a role for erythritol metabolism in virulence is suspected. A chromosomal fragment from the pathogenic strain B. abortus 2308 containing genes for the utilization of erythritol was cloned taking advantage of an erythritol-sensitive Tn5 insertion mutant. The nucleotide sequence of the complete 7714 bp fragment was determined. Four ORFs were identified in the sequence. The four genes were closely spaced, suggesting that they were organized as a single operon (the ery operon). The first gene (eryA) encoded a 519 aa putative erythritol kinase. The second gene (eryB) encoded an erythritol phosphate dehydrogenase. The function of the third gene (eryC) product was tentatively assigned as D-erythrulose-1-phosphate dehydrogenase and the fourth gene (eryD) encoded a regulator of ery operon expression. The operon promoter was located 5' to eryA, and contained an IHF (integration host factor) binding site. Transcription from this promoter was repressed by EryD, and stimulated by erythritol. Functional IHF was required for expression of the operon in Escherichia coli, suggesting a role for IHF in its regulation in B. abortus. The results obtained will be helpful in clarifying the role of erythritol metabolism in the virulence of Brucella spp.

Mycobacterium avium infection of epithelial cells results in inhibition or delay in the release of interleukin-8 and RANTES

Mycobacterium avium is an opportunistic pathogen in AIDS patients, who acquire the infection mainly through the gastrointestinal tract. Previous studies in vitro have shown that M. avium invades epithelial cells of both intestinal and laryngeal origin. In addition, M. avium enters the intestinal mucosa of healthy mice. Because M. avium invasion of the intestinal mucosa in vivo initially is not accompanied by significant influx of inflammatory cells, we sought to determine whether M. avium would trigger chemokine release upon entry into epithelial cells by using HT-29 intestinal and HEp-2 laryngeal epithelial cell lines. Chemokine synthesis was measured both by the presence of specific mRNA and protein secretion in the cell culture supernatant as determined by enzyme-linked immunosorbent assay. Infection of HT-29 intestinal cells with M. avium did not induce the release of interleukin-8 (IL-8) or RANTES for up to 7 days postinfection. However, infection of HEp-2 cells resulted in the release of IL-8 and RANTES at 72 h. Similar findings were observed with other AIDS M. avium isolates belonging to different serovars. Secretion of IL-8 by HEp-2 cells was dependent upon bacterial uptake. In addition, prior infection with M. avium suppressed IL-8 production by HT-29 cells infected with Salmonella typhimurium. Our results suggest that M. avium infection of epithelial cells is associated with a delay in IL-8 and RANTES production which, in the case of HT-29, is prolonged up to 1 week. These findings may explain the weak inflammatory response after intestinal mucosa invasion in mice and are probably related with the ability of the bacterium to evade the host's immune response.

Mycobacterium avium interaction with macrophages and intestinal epithelial cells

Mycobacterium avium is an environmental microorganism that is adapted to live both in the environment (mainly in water and soil) and in bird, fish and mammal hosts. In humans, M. avium infection is seen in patients with some sort of immunosuppression, such as patients with chronic lung disease, and Acquired Immunodeficiency Syndrome. More recently, other populations were shown to be at risk to develop M. avium disease. For the majority of time, humans acquire M. avium through the intestinal tract where the bacterium comes in contact with and translocates the intestinal mucosa. M. avium possesses a unique manner to interact with the intestinal mucosa, and, following invasion, can enter and survive within macrophages and monocytes. Although in vitro entry seems to be dependent on binding to the complement receptor, this finding has not been observed in vivo where the bacterium appears to enter macrophages by alternative mechanisms. The bacterium appears to trigger little inflammatory response, and is able to adapt itself to different environments in the host.

The defect in the metabolism of erythritol of the Brucella abortus B19 vaccine strain is unrelated with its attenuated virulence in mice

The role of the defect in erythritol catabolism in the attenuated virulence of Brucella abortus B19 vaccine strain in mice was investigated by means of five different strains: (i) the erythritol sensitive B19 vaccine strain; (ii) a natural erythritol tolerant (NET) mutant obtained spontaneously from B19; (iii) an erythritol resistant derivative from B19 (FJS19) obtained by gene replacement of the deleted ery region; (iv) the erythritol resistant B. abortus 2308 reference virulent strain; and (v) an erythritol sensitive mutant (227 strain) obtained from strain 2308 by transposon insertion in the chromosomal ery region. Besides virulence for mice, erythritol oxidation as well as other phenotypic markers were tested in all the strains. The 2308 and FJS19 strains grew in the presence of erythritol and oxidized the sugar, whereas the B19 and 227 strains did not. The NET strain grew in presence of erythritol but was unable to oxidize it. The B19 vaccine strain and its two erythritol resistant derivatives, NET and FJS19, showed similar residual virulence and splenic time courses in mice. Moreover, the virulent strain 2308 and its erythritol sensitive derivative (227 strain) exhibited similar levels of splenic infection. Altogether, these results demonstrate that the genetic region implicated in erythritol catabolism is not related to the low virulence exhibited by B19 in mice.

Molecular basis of Brucella pathogenicity: an update

Microorganisms belonging to the genus Brucella can infect humans and many species of animals. Virulence of the brucellae is thought to be essentially due to their capacity to survive and replicate within the phagocytic cells. However, many gaps remain in our understanding of this ability of brucellae to elude the bactericidal effects of host phagocytes, and basic questions remain unanswered. Identification of Brucella gene products which are related to intracellular survival, as well as those which contribute to the induction of protective immunity, is critical to elucidate the molecular mechanisms of the pathogenesis of the organism. The present article summarizes the current status of the research on gene products and other structural or metabolic factors associated with virulence of the brucellae.

Improvement of the Brucella abortus B19 vaccine by its preparation in a glycerol based medium

The Brucella abortus B19 vaccine strain differs from other Brucella strains in its sensitivity to erythritol. However, erythritol tolerant (Eri(t)) mutants arise from sensitive cultures of B19 at high rate, and may cause persistence and/or abortion when the vaccine is inoculated on adult cattle. Twelve different batches of B19 have been examined for the presence of Eri(t) mutants. All contained Eri(t) variants at a proportion ranging from 10(-4) to 10(-6). In order to eliminate these mutants from the vaccine cultures, we have developed a minimal medium with glycerol as the sole carbon source, named MMG30. Growth of the parental strain B19 (erythritol sensitive) in this medium was fairly good compared with the growth of its Eri(t) derivatives. Culture of the 12 different batches of B19 in liquid MMG30 produced up to a thousandfold decrease in the proportion of Eri(t) mutants present in the vaccine cultures. Use of this medium to grow B19 could represent an easy and considerable improvement of the vaccine, by the reduction of the presence of potentially dangerous Eri(t) mutants.

The Brucella abortus vaccine strain B19 carries a deletion in the erythritol catabolic genes

Brucella abortus B19, an avirulent strain obtained by spontaneous mutation, is used worldwide as a vaccine for the control of bovine brucellosis. B19 differs from other B. abortus strains in its sensitivity to erythritol. We took advantage of a previously obtained erythritol sensitive Tn5 insertion mutant of B. abortus 2308 to clone the chromosomal region containing erythritol catabolic genes from this representative pathogenic strain and from the vaccine strain B19. Physical mapping with restriction endonucleases and nucleotide sequence determination revealed the existence of a 702 bp long deletion, occurring between two short direct repeats, in the chromosome of B19. This deletion rendered the B19 strain sensitive to erythritol. Two oligonucleotides whose sequences flank this deletion provided an easy method to differentiate B19 from all other B. abortus isolates.

Identification of Brucella abortus B19 vaccine strain by the detection of DNA polymorphism at the ery locus

As sensitivity to erythritol is the main feature of the Brucella abortus B19 vaccine strain, an attempt to define the genetic basis of this phenotypic trait was made in order to explore its usefulness as a means of molecular identification of strain B19. With this purpose, an erythritol-sensitive derivative of B. abortus strain 2308 was generated by Tn5 transposition methods. Restriction fragments from a cloned 13 kb Tn5-containing EcoRI fragment from the ery locus of strain 2308 were used to probe DNA from B. abortus B19 and other Brucella reference strains. Genetic rearrangement in strain B19 was revealed by the display of restriction fragment length polymorphisms at the ery locus. No pattern differences were detected among all other Brucella strains tested. The polymorphism exhibited by B19 represents the first characterization of this vaccine strain at a molecular level, and can be used to distinguish it from all other Brucella species.