Vir Proteins Stabilize VirB5 and Mediate Its Association with the T Pilus of Agrobacterium tumefaciens
Three VirB proteins (VirB1*, VirB2, and VirB5) have been implicated as putative components of the T pilus from Agrobacterium tumefaciens, which likely mediates binding to plant cells followed by transfer of genetic material. Recently, VirB2 was indeed shown to be its major component (E.-M. Lai and C. I. Kado, J. Bacteriol. 180:2711–2717, 1998). Here, the influence of other Vir proteins on the stability and cellular localization of VirB1*, VirB2, and VirB5 was analyzed. Solubility of VirB1* and membrane association of VirB2 proved to be inherent features of these proteins, independent of virulence gene induction. In contrast, cellular levels of VirB5 were strongly reduced in the absence of other Vir proteins, indicating its stabilization by protein-protein interactions. The assembly and composition of the T pilus were analyzed in nopaline strain C58(pTiC58), its flagellum-free derivative NT1REB(pJK270), and octopine strain A348(pTiA6) following optimized virulence gene induction on solid agar medium. In all strains VirB2 was the major pilus component and VirB5 cofractionated during several purification steps, such as ultracentrifugation, gel filtration, and sucrose gradient centrifugation. VirB5 may therefore be directly involved in pilus assembly, possibly as minor component. In contrast, secreted VirB1* showed no association with the T pilus. In-frame deletions in genesvirB1, virB2, virB5, andvirB6 blocked the formation of virulence gene-dependent extracellular high-molecular-weight structures. Thus, an intact VirB machinery as well as VirB2 and VirB5 are required for T-pilus formation.
Quorum-sensing-controlled processes are considered to be important for the competitiveness of microorganisms in the rhizosphere. They affect cell-cell communication, biofilm formation, and antibiotic production, and the GacS-GacA two-component system plays a role as a key regulator. In spite of the importance of this system for the regulation of various processes, strains with a Gac ؊ phenotype are readily recovered from natural habitats. To analyze the influence of quorum sensing and the influence of the production of the antibiotic phenazine-1-carboxamide on rhizosphere colonization by Pseudomonas chlororaphis, a gnotobiotic system based on Arabidopsis thaliana seedlings in soil was investigated. Transposon insertion mutants of P. chlororaphis isolate SPR044 carrying insertions in different genes required for the production of N-acylhomoserine lactones and phenazine-1-carboxamide were generated. Analysis of solitary rhizosphere colonization revealed that after prolonged growth, the population of the wild type was significantly larger than that of the homoserine lactone-negative gacS mutant and that of a phenazine-1-carboxamide-overproducing strain. In cocultivation experiments, however, the population size of the gacS mutant was similar to that of the wild type after extended growth in the rhizosphere. A detailed analysis of growth kinetics was performed to explain this phenomenon. After cells grown to the stationary phase were transferred to fresh medium, the gacS mutant had a reduced lag phase, and production of the stationary-phase-specific sigma factor RpoS was strongly reduced. This may provide a relative competitive advantage in cocultures with other bacteria, because it permits faster reinitiation of growth after a change to nutrient-rich conditions. In addition, delayed entry into the stationary phase may allow more efficient nutrient utilization. Thus, GacS-GacA-regulated processes are not absolutely required for efficient rhizosphere colonization in populations containing the wild type and Gac ؊ mutants.
TraC of IncN Plasmid pKM101 Associates with Membranes and Extracellular High-Molecular-Weight Structures in Escherichia coli
Conjugative transfer of IncN plasmid pKM101 is mediated by the TraI-TraII region-encoded transfer machinery components. Similar to the case for the related Agrobacterium tumefaciens T-complex transfer apparatus, this machinery is needed for assembly of pili to initiate cell-to-cell contact preceding DNA transfer. Biochemical and cell biological experiments presented here show extracellular localization of TraC, as suggested by extracellular complementation of TraC-deficient bacteria by helper cells expressing a functional plasmid transfer machinery (S. C. Winans, and G. C. Walker, J. Bacteriol. 161:402–410, 1985). Overexpression of TraC and its export in large amounts into the periplasm of Escherichia coliallowed purification by periplasmic extraction, ammonium sulfate precipitation, and column chromatography. Whereas TraC was soluble in overexpressing strains, it partly associated with the membranes in pKM101-carrying cells, possibly due to protein-protein interactions with other components of the TraI-TraII region-encoded transfer machinery. Membrane association of TraC was reduced in strains carrying pKM101 derivatives with transposon insertions in genes coding for other essential components of the transfer machinery,traM, traB, traD, andtraE but not eex, coding for an entry exclusion protein not required for DNA transfer. Cross-linking identified protein-protein interactions of TraC in E. coli carrying pKM101 but not derivatives with transposon insertions in essentialtra genes. Interactions with membrane-bound Tra proteins may incorporate TraC into a surface structure, suggested by its removal from the cell by shearing as part of a high-molecular-weight complex. Heterologous expression of TraC in A. tumefaciens partly compensated for the pilus assembly defect in strains deficient for its homolog VirB5, which further supported its role in assembly of conjugative pili. In addition to its association with high-molecular-weight structures, TraC was secreted into the extracellular milieu. Conjugation experiments showed that secreted TraC does not compensate transfer deficiency of TraC-deficient cells, suggesting that extracellular complementation may rely on cell-to-cell transfer of TraC only as part of a bona fide transfer apparatus.
Biomonitoring of pJP4‐carrying Pseudomonas chlororaphis with Trb protein‐specific antisera
The transfer of catabolic genes on conjugative plasmids to indigenous organisms from which they may spread further into the community allows the introduction of new biodegradative pathways for metabolic conversion of pollutants to the community. Biomonitoring of IncP plasmid pJP4-carrying Pseudomonas chlororaphis from the rhizosphere of Arabidopsis thaliana was achieved using antisera specific for proteins from the plasmid transfer machinery. Antisera were generated that recognized TrbC and TrbF, the putative major and minor components of pJP4-determined pili, respectively, and the putative lipoprotein TrbH. Cell fractionation studies showed association of TrbC, TrbF and TrbH with the cells and suggested that TrbC and TrbF are part of extracellular pJP4-determined pili. TrbF and TrbH antisera allowed specific detection of IncP compared with IncN or IncW plasmid-carrying cells and even permitted differentiation between bacteria carrying IncPalpha plasmid RP4 and IncPbeta plasmid pJP4. Immunofluorescence microscopy was applied to detect TrbF and TrbH signal at the cell periphery, allowing distinction from autofluorescing cells and soil debris. In situ experiments showed specific recognition of pJP4-carrying cells from laboratory cultures, as well as from the rhizosphere of A. thaliana grown in natural soil. After co-inoculation of donor P. chlororaphis pJP4 and recipient Ralstonia eutropha, a combination of immunofluorescence and oligonucleotide hybridization techniques permitted the detection of plasmid transfer between both organisms in the A. thaliana rhizosphere. This strategy may be generally applicable for the analysis of plasmid transfer in natural ecosystems.
The Brucella suis Homologue of the Agrobacterium tumefaciens Chromosomal Virulence Operon chvE Is Essential for Sugar Utilization but Not for Survival in Macrophages
Brucella strains possess an operon encoding type IV secretion machinery very similar to that coded by the Agrobacterium tumefaciens virB operon. Here we describe cloning of the Brucella suis homologue of the chvEgguA-gguB operon of A. tumefaciens and characterize the sugar binding protein ChvE (78% identity), which in A. tumefaciens is involved in virulence gene expression. B. suis chvE is upstream of the putative sugar transporter-encoding genes gguA and gguB, also present in A. tumefaciens, but not adjacent to that of a LysR-type transcription regulator. Although results of Southern hybridization experiments suggested that the gene is present in all Brucella strains, the ChvE protein was detected only in B. suis and Brucella canis with A. tumefaciens ChvE-specific antisera, suggesting that chvE genes are differently expressed in different Brucella species. Analysis of cell growth of B. suis and of its chvE or gguA mutants in different media revealed that ChvE exhibited a sugar specificity similar to that of its A. tumefaciens homologue and that both ChvE and GguA were necessary for utilization of these sugars. Murine or human macrophage infections with B. suis chvE and gguA mutants resulted in multiplication similar to that of the wild-type strain, suggesting that virB expression was unaffected. These data indicate that the ChvE and GguA homologous proteins of B. suis are essential for the utilization of certain sugars but are not necessary for survival and replication inside macrophages.Bacteria of the genus Brucella are gram-negative facultative intracellular pathogens of various wild and domestic mammals and can cause severe zoonotic infections in humans. Traditionally, three major species are distinguished by their preference for certain animal hosts: Brucella abortus for cattle, B. melitensis for caprines, and B. suis for hogs. B. melitensis and B. suis account for the majority of clinical cases in humans (12,38).To evade host defenses, Brucella can inhibit neutrophil degranulation and block tumor necrosis factor alpha production by macrophages (8). Acidification of the phagosome is required for survival and multiplication of B. suis in macrophages (35). Secreted factors, which may be released when Brucella is either extracellular or in the acidic phagosome, could possibly play a role in macrophage survival. In this regard, the transposon mutagenesis study of O'Callaghan et al. (31) indicated that Brucella possesses an operon similar to the virB operon of Agrobacterium tumefaciens, which encodes a type IV secretion machinery. The integrity of the virB operon is required for the intracellular multiplication of Brucella, as recently confirmed by signature-tagged mutagenesis both in vitro in a human macrophage infection model (18) and in vivo using mice (21).The A. tumefaciens plasmid-encoded secretory apparatus presumably forms a multicomponent pore which spans both bacterial membranes and allows for transport of a singlestranded DNA-protein complex into a recipient plant or bacterial cell. Brucella exhibit...
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