In the current study, we examined the regulatory interactions of a serine/threonine phosphatase (BA-Stp1), serine/threonine kinase (BA-Stk1) pair in Bacillus anthracis. B. anthracis STPK101, a null mutant lacking BA-Stp1 and BA-Stk1, was impaired in its ability to survive within macrophages, and this correlated with an observed reduction in virulence in a mouse model of pulmonary anthrax. Biochemical analyses confirmed that BA-Stp1 is a PP2C phosphatase and dephosphorylates phosphoserine and phosphothreonine residues. Treatment of BA-Stk1 with BA-Stp1 altered BA-Stk1 kinase activity, indicating that the enzymatic function of BA-Stk1 can be influenced by BA-Stp1 dephosphorylation. Using a combination of mass spectrometry and mutagenesis approaches, three phosphorylated residues, T165, S173, and S214, in BA-Stk1 were identified as putative regulatory targets of BA-Stp1. Further analysis found that T165 and S173 were necessary for optimal substrate phosphorylation, while S214 was necessary for complete ATP hydrolysis, autophosphorylation, and substrate phosphorylation. These findings provide insight into a previously undescribed Stp/Stk pair in B. anthracis.A profile of the intracellular signaling proteins that regulate transition of Bacillus anthracis from dormancy to expression of virulence factors is emerging. Like many prokaryotes, B. anthracis utilizes two-component histidine kinase systems to regulate physiological changes and the expression of virulence factors. These systems include the Spo0 histidine kinase-based phosphorelay pathway (32, 37) and the Bacillus respiratory response A and B system involved in regulating toxin expression (36). Unlike for histidine kinase systems, little is known about reversible serine/threonine phosphorylation events in B. anthracis. These systems are common to eukaryotic cells (3,14,25,40) but were only recently found in prokaryotes to modulate a variety of metabolic and physiological processes (1,2,7,11,12,15,17,24,28,35,38). Whether reversible serine/threonine phosphorylation contributes to similar events in B. anthracis is not known.The current paradigm for prokaryotic serine/threonine kinases (STK) is based in part on the structure of PknB, a serine/threonine kinase from Mycobacterium tuberculosis that is structurally related to eukaryotic Hanks-type kinases (39). PknB autophosphorylates and is dephosphorylated by an M. tuberculosis phosphatase, PstP, in order to alter kinase activity (4). Similar to the findings for PnkB, Madec et al. identified critical autophosphorylated residues and autophosphorylated domains of PrkC, an STK from Bacillus subtilis (22), which suggested that the phosphorylation state of these residues impacts the activation of PrkC (22). These studies suggested that prokaryotic STKs exhibited activities similar to those of their eukaryotic homologs and were regulated by cognate phosphatases. Hence, studies of serine/threonine phosphatase (STP)/STK pairs may help define a core regulatory module in bacterial physiology and virulence, wherein the kinase ...
Clostridium difficile toxin B (TcdB) has been studied extensively by using cell-free systems and tissue culture, but, like many bacterial toxins, the in vivo targets of TcdB are unknown and have been difficult to elucidate with traditional animal models. In the current study, the transparent Danio rerio (zebrafish) embryo was used as a model for imaging of in vivo TcdB localization and organ-specific damage in real time. At 24 h after treatment, TcdB was found to localize at the pericardial region, and zebrafish exhibited the first signs of cardiovascular damage, including a 90% reduction in systemic blood flow and a 20% reduction in heart rate. Within 72 h of exposure to TcdB, the ventricle chamber of the heart became deformed and was unable to contract or pump blood, and the fish exhibited extensive pericardial edema. In line with the observed defects in ventricle contraction, TcdB was found to directly disrupt coordinated contractility and rhythmicity in primary cardiomyocytes. Furthermore, using a caspase-3 inhibitor, we were able to block TcdB-related cardiovascular damage and prevent zebrafish death. These findings present an insight into the in vivo targets of TcdB, as well as demonstrate the strength of the zebrafish embryo as a tractable model for identification of in vivo targets of bacterial toxins and evaluation of novel candidate therapeutics.bacterial toxin ͉ Clostridium difficile-associated disease ͉ large clostridial toxins
SummaryOedema factor (OF) and protective antigen (PA) are secreted by Bacillus anthracis , and their binary combination yields oedema toxin (OT). Following PAmediated delivery to the cytosol, OF functions as an adenylate cyclase generating high levels of cAMP. To assess OT as a possible cause of tissue damage and cell death, a novel approach was developed, which utilized a developing zebrafish embryo model to study toxin activity. Zebrafish embryos incubated with OT exhibited marked necrosis of the liver, cranium and gastrointestinal tract, as well as reduced swim bladder inflation. The OT-treated embryos survived after all stages of development but succumbed to the toxin within 7 days. Additional analysis of specific cell lines, including macrophage and non-macrophage, showed OT-induced cell death is cell type-specific. There was no discernible correlation between levels of OF-generated cAMP and cell death. Depending on the type of cell analysed, cell death could be detected in low levels of cAMP, and, conversely, cell survival was observed in one cell line in which high levels of cAMP were found following treatment with OT. Collectively, these data suggest OT is cytotoxic in a celldependent manner and may contribute to disease through direct cell killing leading to tissue necrosis.
In an effort to better understand the mechanisms by which Bacillus anthracis establishes disease, experiments were undertaken to identify the genes essential for intracellular germination. Eighteen diverse genetic loci were identified via an enrichment protocol using a transposon-mutated library of B. anthracis spores, which was screened for mutants delayed in intracellular germination. Fourteen transposon mutants were identified in genes not previously associated with B. anthracis germination and included disruption of factors involved in membrane transport, transcriptional regulation, and intracellular signaling. Four mutants contained transposon insertions in gerHA, gerHB, gerHC, and pagA, respectively, each of which has been previously associated with germination or survival of B. anthracis within macrophages. Strain MIGD101 (named for macrophage intracellular germination defective 101) was of particular interest, since this mutant contained a transposon insertion in an intergenic region between BAs2807 and BAs2808, and was the most highly represented mutant in the enrichment. Analysis of B. anthracis MIGD101 by confocal microscopy and differential heat sensitivity following macrophage infection revealed ungerminated spores within the cell. Moreover, B. anthracis MIGD101 was attenuated in cell killing relative to the parent strain. Further experimental analysis found that B. anthracis MIGD101 was defective in five known B. anthracis germination pathways, supporting a mechanism wherein the intergenic region between BAs2807 and BAs2808 has a global affect on germination of this pathogen. Collectively, these findings provide insight into the mechanisms supporting B. anthracis germination within host cells.Bacillus anthracis spores germinate during early stages of inhalational anthrax, and this is considered to be a critical step in the progression of anthrax disease (4, 5, 7). Indeed, transition from dormant spore to vegetative bacilli is essential for growth, bacteremia, toxin production, and synthesis of a poly-D-glutamic acid capsule, each of which is important to the virulence of B. anthracis.Results from a series of studies indicate B. anthracis spores are engaged by, and can germinate within, alveolar macrophages (13, 15). Sanz et al. recently described the detection of B. anthracis spores in alveolar macrophages under in vivo infection conditions using a mouse model of inhalational anthrax (15). The molecular basis of spore tropism for alveolar macrophages may be due to the collagenlike exosporium protein, BclA, which interacts with the macrophage receptor, Mac-1 (13), while at the same time preventing the interaction of spores with other types of cells. Spores are taken up by Mac-1-dependent phagocytosis into LAMP-1 positive vesicles, where germination is triggered, and the germinated spores become susceptible to killing by the macrophage (10).Very little is known about the bacterial factors that promote, repress, or otherwise regulate germination of B. anthracis spores within macrophages. To date, expe...
Clostridium sordellii lethal toxin (TcsL) is distinct among large clostridial toxins (LCTs), as it is markedly reduced in its rate of intoxication at pH 8.0 yet is cytotoxic at pH 4.0. Results from the present study suggest that TcsL's slow rate of intoxication at pH 8.0 is linked to formation of a high-molecular-weight complex containing dissociable pH 4.0-sensitive polypeptides. The cytosolic delivery of TcsL's enzymatic domain by using a surrogate cell entry system resulted in cytopathic effect rates similar to those of other LCTs at pH 8.0, further indicating that rate-limiting steps occurred at the point of cell entry. Since these rate-limiting steps could be overcome at pH 4.0, TcsL was examined across a range of pH values and was found to dissociate into distinct 45-to 55-kDa polypeptides between pH 4.0 and pH 5.0. The polypeptides reassociated when shifted back to pH 8.0. At pH 8.0, this complex was resistant to sodium dodecyl sulfate (SDS) and multiple proteases; however, following dissociation, the polypeptides became protease sensitive. Dissociation of TcsL, and cytotoxicity, could be blocked by preincubation with ethylene glycol bis(sulfosuccinimidylsuccinate), resulting in cross-linking of the polypeptides. TcsL was also examined at pH 8.0 by using SDS-agarose gel electrophoresis and transmission electron microscopy and was found to exist in a higher-molecular-weight complex which resolved at a size exceeding 750 kDa and also dissociated at pH 4.0. However, this complex did not reassemble following a shift back to pH 8.0. Collectively, these data suggest that TcsL is maintained in a protease-resistant, high-molecular-weight complex, which dissociates at pH 4.0, leading to cytotoxicity.
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