Bordetella are Gram negative bacteria that cause respiratory tract infections in humans and animals. While at least five different species of Bordetella are known to exist, this review focuses on B. pertussis, B. bronchiseptica and B. parapertussis subspecies. In their virulent phase, all of these bacteria produce a nearly identical set of virulence factors which include adhesins such as filamentous hemagglutinin (FHA), fimbriae and pertactin, as well as toxins such as a bifunctional adenylate cyclase/hemolysin, dermonecrotic toxin, tracheal cytotoxin, a B. pertussis specific pertussis toxin and B. bronchiseptica specific type III secreted proteins. Expression of nearly all of these virulence factors is positively regulated by the products of the bvgAS locus. BvgA and BvgS comprise a two-component signal transduction system that mediates transition between at least three identifiable phases---a virulent (Bvg+) phase, an avirulent (Bvg-) phase and an intermediate (Bvg(i)) phase---in response to specific environmental signals. Bordetella colonize the ciliated respiratory mucosa, a surface designed to eliminate foreign particles, thereby making the adherence and persistence mechanisms of these bacteria crucial. The development of relevant animal models for B. bronchiseptica has enabled us to study Bordetella pathogenesis in the context of natural host-pathogen interactions. In addition, evolutionary studies across the various Bordetella species and detailed analysis of differential regulation of Bvg-activated/repressed genes has greatly enhanced our understanding of the mechanisms of Bordetella pathogenesis.
). E. faecium strain 4 is highly susceptible to PLA 2 (LD 50 ∼50 ng/ml), whereas E. faecium strain 6 is less susceptible to PLA 2 (LD 50 ∼500 ng/ml).The S. aureus strains were grown overnight at 37°C, washed once, and then subcultured for either 2.5-3 h (mid-logarithmic phase) or ∼18 h (stationary phase) in fresh Trypticase Soy Broth (TSB; Difco Laboratories, Detroit, Michigan, USA) at a starting
SummaryThe Bordetella bronchiseptica type III (TIII) secretion system induces cytotoxicity in infected macrophages and epithelial cells. In this report we characterize the cell death phenotype and compare it to the TIII-dependent cytotoxicity induced by Yersinia enterocolitica and Shigella flexneri . Bordetella bronchiseptica strain RB58 was able to induce cell death in J774A.1 macrophages with the same efficiency as Shigella and Yersinia , but only B. bronchiseptica was able to kill epithelial cells in a TIII-dependent manner. Primary macrophages from caspase 1 -/-mice were susceptible to RB58-mediated killing, suggesting that unlike Shigella and Salmonella , caspase 1 does not mediate cell death. RB58-induced cytotoxicity was not inhibited by addition of the pan-caspase inhibitor zVAD, and Western blot analyses of RB58-infected HeLa cells indicated that neither caspase 3 nor 7 was cleaved and PARP remained in its full-length active form. Morphologically the RB58-infected HeLa cells resembled necrotic rather than apoptotic cells, exhibiting cytoplasmic swelling and extensive membrane blebbing in the absence of nuclear changes. The addition of exogenous glycine, which has been shown to prevent necrotic cell death by blocking non-specific ion fluxes across the plasma membrane, blocked RB58-induced cytotoxicity. Addition of cyclosporin A which prevents the opening of the mitochondrial permeability pore, had no effect on RB58-infected cells. We conclude that the B. bronchiseptica TIII secretion system induces a mode of cell death consistent with necrosis that is distinct from that of Yersinia and Shigella .
We have recently described a multicomponent cascade that regulates type III secretion in Bordetella. This cascade includes a group of proteins, BtrU, BtrW, and BtrV, that contain an array of domains that define partner-switching complexes previously characterized in gram-positive bacteria. BtrU contains a PP2C-like serine phosphatase domain, BtrW contains a serine kinase/anti-sigma factor motif, and BtrV includes an anti-sigma factor antagonist domain. On the basis of genetic studies and sequence similarity with the RsbURsbW-RsbV and SpoIIE-SpoIIAB-SpoIIAA partner switchers of Bacillus subtilis, a series of interactions between Bordetella orthologs have been proposed. Bacterial two-hybrid analysis, tagged protein pull-downs, and in vitro phosphorylation assays were used to characterize interactions between BtrW and BtrV. In addition, BtrV mutants predicted to mimic a constitutively phosphorylated form of BtrV or to be nonphosphorylatable and BtrW mutants defective in serine kinase activity or the ability to bind BtrV were constructed and analyzed. Our results demonstrate that (i) BtrW and BtrV interact with each other, (ii) BtrW phosphorylates BtrV at serine S55, (iii) the conserved serine residue S55 of BtrV plays a key role in BtrV-BtrW interactions, and (iv) the ability of BtrW to phosphorylate BtrV and disrupt BtrV-BtrW binding is essential for the type III secretion process.
Intranasal inoculation of mice with Bordetella bronchiseptica produces a transient pneumonia that is cleared over several weeks in a process known to require both neutrophils and lymphocytes. In this study, we evaluated the roles of the chemokines MIG (CXCL9), IP-10 (CXCL10), and I-TAC (CXCL11) and their common receptor, CXCR3. Following bacterial inoculation, message expression of interleukin-1 (IL-1), IL-6, and the neutrophil-attracting chemokines KC, LIX, and MIP-2 was rapidly induced, with maximal expression found at 6 h. In contrast, message expression of gamma interferon, MIG, IP-10, and I-TAC peaked at 2 days. Expression of all of these chemokines and cytokines returned to near baseline by 5 days, despite the persistence of high levels of live bacteria at this time. Induced MIG, IP-10, and I-TAC protein expression was localized in areas of inflammation at 2 to 3 days and was temporally associated with increased levels of CXCR3 ؉ lymphocytes in bronchoalveolar lavage fluid. There was no increase in mortality in mice lacking CXCR3. However, the clearance of bacteria from the lung and trachea was delayed, and the recruitment of lymphocytes and NK cells was slightly decreased, for CXCR3 ؊/؊ mice relative to CXCR3 ؉/؉ mice. We conclude that the CXCR3 receptor-ligand system contributes to pulmonary host defense in B. bronchiseptica infection by recruiting lymphocytes and NK cells into the lung.
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