The small RNA ErsA of Pseudomonas aeruginosa, transcribed from the same genomic context of the well-known Escherichia coli Spot 42, has been characterized. We show that, different from Spot 42, ErsA is under the transcriptional control of the envelope stress response, which is known to impact the pathogenesis of P. aeruginosa through the activity of the alternative sigma factor σ(22) . The transcriptional responsiveness of ErsA RNA also spans infection-relevant cues that P. aeruginosa can experience in mammalian hosts, such as limited iron availability, temperature shifts from environmental to body temperature and reduced oxygen conditions. Another difference between Spot 42 and ErsA is that ErsA does not seem to be involved in the regulation of carbon source catabolism. Instead, our results suggest that ErsA is linked to anabolic functions for the synthesis of exoproducts from sugar precursors. We show that ErsA directly operates in the negative post-transcriptional regulation of the algC gene that encodes the virulence-associated enzyme AlgC, which provides sugar precursors for the synthesis of several P. aeruginosa polysaccharides. Like ErsA, the activation of algC expression is also dependent on σ(22) . Altogether, our results suggest that ErsA and σ(22) combine in an incoherent feed-forward loop to fine-tune AlgC enzyme expression.
The high prevalence of hypermutable (mismatch repair-deficient) Pseudomonas aeruginosa strains in patients with cystic fibrosis (CF) is thought to be driven by their co-selection with adaptive mutations required for long-term persistence. Whether the increased mutation rate of naturally hypermutable strains is associated with a biological benefit or cost for the colonization of secondary environments is not known. Thirty-nine P. aeruginosa strains were collected from ten patients with CF during their course of chronic lung infections and screened for hypermutability. Seven hypermutable P. aeruginosa strains (18 %) isolated from six patients with CF (60 %) were identified and assigned to five different genotypes. Complementation and sequence analysis in the mutS, mutL and uvrD genes of these hypermutable P. aeruginosa strains revealed novel mutations. To understand the consequences of hypermutation for the fitness of the organisms, five pairs of clinical wild-type/hypermutable, clonally related P. aeruginosa strains and the laboratory strains PAO1/ PAO1DmutS were subjected to competition in vitro and in the agar-beads mouse model of chronic airway infection. When tested in competition assay in vitro, the wild-type outcompeted four clinical hypermutable strains and the PAO1DmutS strain. In vivo, all of the hypermutable strains were less efficient at establishing lung infection than their wild-type clones. These results suggest that P. aeruginosa hypermutation is associated with a biological cost, reducing the potential for colonization of new environments and therefore strain transmissibility.
Pseudomonas aeruginosa is a highly adaptable bacterium that thrives in a broad range of ecological niches and can infect multiple hosts as diverse as plants, nematodes and mammals. In humans, it is an important opportunistic pathogen. This wide adaptability correlates with its broad genetic diversity. In this study, we used a deep-sequencing approach to explore the complement of small RNAs (sRNAs) in P. aeruginosa as the number of such regulatory molecules previously identified in this organism is relatively low, considering its genome size, phenotypic diversity and adaptability. We have performed a comparative analysis of PAO1 and PA14 strains which share the same host range but differ in virulence, PA14 being considerably more virulent in several model organisms. Altogether, we have identified more than 150 novel candidate sRNAs and validated a third of them by Northern blotting. Interestingly, a number of these novel sRNAs are strain-specific or showed strain-specific expression, strongly suggesting that they could be involved in determining specific phenotypic traits.
The sequence elements determining the binding of the sigma54-containing RNA polymerase (sigma54-RNAP) to the Pu promoter of Pseudomonas putida have been examined. Contrary to previous results in related systems, we show that the integration host factor (IHF) binding stimulates the recruitment of the enzyme to the -12/-24 sequence motifs. Such a recruitment, which is fully independent of the activator of the system, XylR, requires the interaction of the C-terminal domain of the alpha subunit of RNAP with specific DNA sequences upstream of the IHF site which are reminiscent of the UP elements in sigma70 promoters. Our data show that this interaction is mainly brought about by the distinct geometry of the promoter region caused by IHF binding and the ensuing DNA bending. These results support the view that binding of sigma54-RNAP to a promoter is a step that can be subjected to regulation by factors (e.g. IHF) other than the sole intrinsic affinity of sigma54-RNAP for the -12/-24 site.
In order to study the toluene and o-xylene catabolic genes of Pseudomonas stutzeri OX1, a genomic library was constructed. A 28-kb EcoRI restriction endonuclease DNA fragment, cloned into the vector plasmid pLAFR1 and designated pFB3401, permitted Pseudomonas putida PaW340 to convert toluene and o-xylene into the corresponding meta-ring fission products. Physical and functional endonuclease restriction maps have been derived from the cloned DNA fragment. Further subcloning into and deletion analysis in the Escherichia coli vector pGEM-3Z allowed the genes for the conversion of toluene or o-xylene into the corresponding catechols to be mapped within a 6-kb region of the pFB3401 insert and their direction of transcription to be determined. Following exposure to toluene, E. coli cells carrying this 6-kb region produce a mixture of o-cresol, m-cresol, and p-cresol, which are further converted to 3-methylcatechol and 4-methylcatechol. Similarly, a mixture of 2,3-dimethylphenol and 3,4-dimethylphenol, further converted into dimethylcatechols, was detected after exposure to o-xylene. The enzyme involved in the first step of toluene and o-xylene degradation exhibited a broad substrate specificity, being able to oxidize also benzene, ethylbenzene, m-xylene, p-xylene, styrene, and naphthalene. Deletions of the 6-kb region which affect the ability to convert toluene or o-xylene into the corresponding methylphenols compromise also their further oxidation to methylcatechols. This suggests that a single enzyme system could be involved in both steps of the early stages of toluene and o-xylene catabolism.
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