- Volume 157, Issue 8, 2011
Volume 157, Issue 8, 2011
- Microbial Pathogenicity
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Superoxide dismutase C is required for intracellular survival and virulence of Burkholderia pseudomallei
Burkholderia pseudomallei is an intracellular pathogen and the causative agent of melioidosis, a life-threatening disease of humans. Within host cells, superoxide is an important mediator of pathogen killing. In this study, we have identified the B. pseudomallei K96243 sodC gene, shown that it has superoxide dismutase activity, and constructed an allelic deletion mutant of this gene. Compared with the wild-type, the mutant was more sensitive to killing by extracellular superoxide, but not to superoxide generated intracellularly. The sodC mutant showed a markedly decreased survival in J774A.1 mouse macrophages, and reduced numbers of bacteria were recovered from human polymorphonuclear neutrophils (PMNs) when compared with the wild-type. The numbers of wild-type or mutant bacteria recovered from human diabetic neutrophils were significantly lower than from normal human neutrophils. The sodC mutant was attenuated in BALB/c mice. Our results indicate that SodC plays a key role in the virulence of B. pseudomallei, but that diabetics are not more susceptible to infection because of a reduced ability of PMNs to kill by superoxide.
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- Physiology And Biochemistry
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Genetic characterization of enzymes involved in the priming steps of oxytetracycline biosynthesis in Streptomyces rimosus
More LessTetracyclines are clinically important aromatic polyketides whose biosynthesis is catalysed by bacterial type II polyketide synthases (PKSs). Tetracyclines are biosynthesized starting with an amide-containing malonamate starter unit and the resulting C-2 carboxyamide is critical for the antibiotic activities. In this work, we genetically verified that an amidotransferase, OxyD, and a thiolase, OxyP, are involved in the biosynthesis and incorporation of the starter unit. First, two mutations, R248T and D268N, were found to be present in OxyD* encoded in Streptomyces rimosus ATCC 13224, a strain that produces the acetate-primed 2-acetyl-2-decarboxyamido-oxytetracycline (ADOTC) instead of the malonamate-primed oxytetracycline (OTC). Homology modelling suggested that in particular D268N may inactivate OxyD. Complementation of S. rimosus ATCC 13224 with wild-type OxyD restored OTC biosynthesis, thereby confirming the essential role of OxyD in the synthesis of the amide starter unit. Second, using a series of knockout and complementation approaches, we demonstrated that OxyP is most likely involved in maintaining fidelity of the amide-priming process via hydrolysis of the competing acetate priming starter units. While the inactivation of OxyP does not eliminate OTC biosynthesis, the ratio of acetate-primed ADOTC to malonamate-primed OTC is significantly increased. This suggests that OxyP plays an ancillary role in OTC biosynthesis and is important for minimizing the levels of ADOTC, a shunt product that has much weaker antibiotic activities than OTC.
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Redundancy and specificity of multiple trigger factor chaperones in Desulfitobacteria
More LessThe ribosome-bound trigger factor (TF) chaperone assists folding of newly synthesized polypeptides and participates in the assembly of macromolecular complexes. In the present study we showed that multiple distinct TF paralogues are present in genomes of Desulfitobacteria, a bacterial genus known for its ability to grow using organohalide respiration. Two full-length TF chaperones and at least one truncated TF (lacking the N-terminal ribosome-binding domain) were identified, the latter being systematically linked to clusters of reductive dehalogenase genes encoding the key enzymes in organohalide respiration. Using a well-characterized heterologous chaperone-deficient Escherichia coli strain lacking both TF and DnaK chaperones, we demonstrated that all three TF chaperones were functional in vivo, as judged by their ability to partially suppress bacterial growth defects and protein aggregation in the absence of both major E. coli chaperones. Next, we found that the N-terminal truncated TF-like protein PceT functions as a dedicated chaperone for the cognate reductive dehalogenase PceA by solubilizing and stabilizing it in the heterologous system. Finally, we showed that PceT specifically interacts with the twin-arginine signal peptide of PceA. Taken together, our data define PceT (and more generally the new RdhT family) as a class of TF-like chaperones involved in the maturation of proteins secreted by the twin-arginine translocation pathway.
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A conserved residue, PomB-F22, in the transmembrane segment of the flagellar stator complex, has a critical role in conducting ions and generating torque
More LessBacterial flagellar motors exploit the electrochemical potential gradient of a coupling ion (H+ or Na+) as their energy source, and are composed of stator and rotor proteins. Sodium-driven and proton-driven motors have the stator proteins PomA and PomB or MotA and MotB, respectively, which interact with each other in their transmembrane (TM) regions to form an ion channel. The single TM region of PomB or MotB, which forms the ion-conduction pathway together with TM3 and TM4 of PomA or MotA, respectively, has a highly conserved aspartate residue that is the ion binding site and is essential for rotation. To investigate the ion conductivity and selectivity of the Na+-driven PomA/PomB stator complex, we replaced conserved residues predicted to be near the conserved aspartate with H+-type residues, PomA-N194Y, PomB-F22Y and/or PomB-S27T. Motility analysis revealed that the ion specificity was not changed by either of the PomB mutations. PomB-F22Y required a higher concentration of Na+ to exhibit swimming, but this effect was suppressed by additional mutations, PomA-N194Y or PomB-S27T. Moreover, the motility of the PomB-F22Y mutant was resistant to phenamil, a specific inhibitor for the Na+ channel. When PomB-F22 was changed to other amino acids and the effects on swimming ability were investigated, replacement with a hydrophilic residue decreased the maximum swimming speed and conferred strong resistance to phenamil. From these results, we speculate that the Na+ flux is reduced by the PomB-F22Y mutation, and that PomB-F22 is important for the effective release of Na+ from PomB-D24.
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Volumes and issues
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