SummaryIn Escherichia coli and some other g g g g -Proteobacteria, the alternative s s s s factor RpoS functions as a regulator of the general stress response. The role of RpoS in Pseudomonas aeruginosa is not clear. Although P. aeruginosa RpoS contributes to the resistance to several environmental stresses, its role appears to be less pivotal than in E. coli . In P. aeruginosa , RpoS also regulates the production of several virulence factors and influences the expression of individual genes that are controlled by quorum sensing. Some quorum-controlled genes are induced by RpoS, whereas others are repressed. To gain insights about RpoS function in P. aeruginosa and to understand better the regulation of quorum-controlled genes, we used transcript profiling to define an RpoS regulon. We identified 772 genes regulated by RpoS in stationary but not in logarithmic growth phase (504 were induced and 268 were repressed), and we identified putative RpoS promoter sequence elements with similarity to the E. coli RpoS consensus in several of these genes. Many genes in the regulon, for example a set of chemotaxis genes, have assigned functions that are distinct from those in E. coli and are not obviously related to a stress response. Furthermore, RpoS affects the expression of more than 40% of all quorum-controlled genes identified in our previous transcriptome analysis. This highlights the significance of RpoS as a global factor that controls quorum-sensing gene expression at the onset of stationary phase. The transcription profiling results have allowed us to build a model that accommodates previous seemingly conflicting reports.
Flagella act as semirigid helical propellers that are powered by reversible rotary motors. Two membrane proteins, MotA and MotB, function as a complex that acts as the stator and generates the torque that drives rotation. The genome sequence of Pseudomonas aeruginosa PAO1 contains dual sets of motA and motB genes, PA1460-PA1461 (motAB) and PA4954-PA4953 (motCD), as well as another gene, motY (PA3526), which is known to be required for motor function in some bacteria. Here, we show that these five genes contribute to motility. Loss of function of either motAB-like locus was dispensable for translocation in aqueous environments. However, swimming could be entirely eliminated by introduction of combinations of mutations in the two motAB-encoding regions. Mutation of both genes encoding the MotA homologs or MotB homologs was sufficient to abolish motility. Mutants carrying double mutations in nonequivalent genes (i.e., motA motD or motB motC) retained motility, indicating that noncognate components can function together. motY appears to be required for motAB function. The combination of motY and motCD mutations rendered the cells nonmotile. Loss of function of motAB, motY, or motAB motY produced similar phenotypes; although the swimming speed was only reduced to ϳ85% of the wild-type speed, translocation in semisolid motility agar and swarming on the surface of solidified agar were severely impeded. Thus, the flagellar motor of P. aeruginosa represents a more complex configuration than the configuration that has been studied in other bacteria, and it enables efficient movement under different circumstances.
Pseudomonas aeruginosa, a ␥-proteobacterium, is motile by means of a single polar flagellum and is chemotactic to a variety of organic compounds and phosphate. P. aeruginosa has multiple homologues of Escherichia coli chemotaxis genes that are organized into five gene clusters. Previously, it was demonstrated that genes in cluster I and cluster V are essential for chemotaxis. A third cluster (cluster II) contains a complete set of che genes, as well as two genes, mcpA and mcpB, encoding methyl-accepting chemotaxis proteins. Mutations were constructed in several of the cluster II che genes and in the mcp genes to examine their possible contributions to P. aeruginosa chemotaxis. A cheB2 mutant was partially impaired in chemotaxis in soft-agar swarm plate assays. Providing cheB2 in trans complemented this defect. Further, overexpression of CheB2 restored chemotaxis to a completely nonchemotactic, cluster I, cheB-deficient strain to near wild-type levels. An mcpA mutant was defective in chemotaxis in media that were low in magnesium. The defect could be relieved by the addition of magnesium to the swarm plate medium. An mcpB mutant was defective in chemotaxis when assayed in dilute rich soft-agar swarm medium or in minimal-medium swarm plates containing any 1 of 60 chemoattractants. The mutant phenotype could be complemented by the addition of mcpB in trans. Overexpression of either McpA or McpB in P. aeruginosa or Escherichia coli resulted in impairment of chemotaxis, and these cells had smooth-swimming phenotypes when observed under the microscope. Expression of P. aeruginosa cheA2, cheB2, or cheW2 in E. coli K-12 completely disrupted wild-type chemotaxis, while expression of cheY2 had no effect. These results indicate that che cluster II genes are expressed in P. aeruginosa and are required for an optimal chemotactic response.Chemotaxis, the directed movement towards chemicals in the environment, is a behavioral response exhibited by most flagellated bacteria. Escherichia coli and Salmonella enterica serovar Typhimurium have served as prototype organisms for studying chemotaxis, and the signal transduction pathway used to effect a chemotactic response in these ␥-proteobacteria is a paradigm for "two-component" and histidine kinase phosphosignaling pathways (5,6,54,55). A set of six chemotaxis proteins acts in concert with receptors called methyl-accepting chemotaxis proteins (MCPs). The current model is that MCPs exist as homodimers that are physically associated with a CheW linker protein dimer and a CheA dimer. There is evidence that these dimeric signaling units exist in cells as supermolecular complexes that are arranged as trimers of dimers (30, 51). On binding an amino acid or other attractant, an MCP dimer undergoes a conformational change that initiates sensory signal transduction by altering the activity of CheA, which is a sensor histidine kinase. CheA-P is a phosophodonor for the response regulator protein, CheY. CheY-P is mobile in the cell and interacts with the rotational "switch" protein FliM in th...
Previous research suggests that the attachment style developed during childhood informs adult attachment styles, which in turn affects adult relationships and responses to stress. This study considers the sources of stress in hospice nurses and addresses the potential impact of their attachment styles on stress and coping experiences. Adult attachment style, stress and coping were measured in 84 nurses recruited from five hospices. The results supported previous research regarding the most common sources of stress in this nursing group. The study found partial support for the hypothesis that nurses with insecure attachment styles experience more stress than securely attached nurses. Hospice nurses with a fearful or dismissing attachment style were found to be less likely to seek emotional social support as a means of coping with stress than hospice nurses with a secure or preoccupied attachment style. Supervision, support and career-long training for nurses in hospices are recommended. Further research is needed to clarify the involvement of attachment style in hospice nurse stress and coping experiences.
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