Histone-like nucleoid structuring protein (H-NS) is a modular protein that is associated with the bacterial nucleoid. We used chromatin immunoprecipitation to determine the binding sites of H-NS and RNA polymerase on the Salmonella enterica serovar Typhimurium chromosome. We found that H-NS does not bind to actively transcribed genes and does not co-localize with RNA polymerase. This shows that H-NS principally silences gene expression by restricting the access of RNA polymerase to the DNA. H-NS had previously been shown to preferentially bind to curved DNA in vitro. In fact, at the genomic level we discovered that the level of H-NS binding correlates better with the AT-content of DNA. This is likely to have evolutionary consequences because we show that H-NS binds to many Salmonella genes acquired by lateral gene transfer, and functions as a gene silencer. The removal of H-NS from the cell causes un-controlled expression of several Salmonella pathogenicity islands, and we demonstrate that this has deleterious consequences for bacterial fitness. Our discovery of this novel role for H-NS may have implications for the acquisition of foreign genes by enteric bacteria.
Despite being nutrient rich, the tissues and fluids of vertebrates are hostile to microorganisms, and most bacteria that attempt to take advantage of this environment are rapidly eliminated by host defences. Pathogens have evolved various means to promote their survival in host tissues, including stress responses that enable bacteria to sense and adapt to adverse conditions. Many different stress responses have been described, some of which are responsive to one or a small number of cues, whereas others are activated by a broad range of insults. The surface layers of pathogenic bacteria directly interface with the host and can bear the brunt of the attack by the host armoury. Several stress systems that respond to perturbations in the microbial cell outside of the cytoplasm have been described and are known collectively as extracytoplasmic or envelope stress responses (ESRs). Here, we review the role of the ESRs in the pathogenesis of Gram-negative bacterial pathogens.
Salmonella is a widespread zoonotic enteropathogen that causes gastroenteritis and fatal typhoidal disease in mammals. During systemic infection of mice, Salmonella enterica serovar Typhimurium resides and replicates in macrophages within the "Salmonella-containing vacuole" (SCV). It is surprising that the substrates and metabolic pathways necessary for growth of S. Typhimurium within the SCV of macrophages have not been identified yet. To determine whether S. Typhimurium utilized sugars within the SCV, we constructed a series of S. Typhimurium mutants that lacked genes involved in sugar transport and catabolism and tested them for replication in mice and macrophages. These mutants included a mutant with a mutation in the pfkAB-encoded phosphofructokinase, which catalyzes a key committing step in glycolysis. We discovered that a pfkAB mutant is severely attenuated for replication and survival within RAW 264.7 macrophages. We also show that disruption of the phosphoenolpyruvate:carbohydrate phosphotransferase system by deletion of the ptsHI and crr genes reduces S. Typhimurium replication within RAW 264.7 macrophages. We discovered that mutants unable to catabolize glucose due to deletion of ptsHI, crr, and glk or deletion of ptsG, manXYZ, and glk showed reduced replication within RAW 264.7 macrophages. This study proves that S. Typhimurium requires glycolysis for infection of mice and macrophages and that transport of glucose is required for replication within macrophages.
The Gram-negative bacterial envelope is an essential interface between the intracellular and harsh extracellular environment. Envelope stress responses (ESRs) are crucial to the maintenance of this barrier and function to detect and respond to perturbations in the envelope, caused by environmental stresses. Pathogenic bacteria are exposed to an array of challenging and stressful conditions during their lifecycle and, in particular, during infection of a host. As such, maintenance of envelope homeostasis is essential to their ability to successfully cause infection. This review will discuss our current understanding of the σE- and Cpx-regulated ESRs, with a specific focus on their role in the virulence of a number of model pathogens.
The extracytoplasmic function sigma factor, s E , has been shown to play a critical role in virulence of Salmonella enterica serovar Typhimurium (S. Typhimurium). The previously optimized two-plasmid system has been used to identify S. Typhimurium promoters recognized by RNA polymerase containing s E . This method allowed identification of 34 s E -dependent promoters that direct expression of 62 genes in S. Typhimurium, 23 of which (including several specific for S. Typhimurium) have not been identified previously to be dependent upon s E in Escherichia coli. The promoters were confirmed in S. Typhimurium and transcriptional start points of the promoters were determined by S1-nuclease mapping. All the promoters contained sequences highly similar to the consensus sequence of s E -dependent promoters. The identified genes belonging to the S.Typhimurium s E -regulon encode proteins involved in primary metabolism, DNA repair systems and outer-membrane biogenesis, and regulatory proteins, periplasmic proteases and folding factors, proposed lipoproteins, and inner-and outer-membrane proteins with unknown functions. Several of these s E -dependent genes have been shown to play a role in virulence of S. Typhimurium.
Global agricultural emissions of the greenhouse gas nitrous oxide (N 2 O) have increased by around 20% over the last 100 y, but regulation of these emissions and their impact on bacterial cellular metabolism are poorly understood. Denitrifying bacteria convert nitrate in soils to inert di-nitrogen gas (N 2 ) via N 2 O and the biochemistry of this process has been studied extensively in Paracoccus denitrificans. Here we demonstrate that expression of the gene encoding the nitrous oxide reductase (NosZ), which converts N 2 O to N 2 , is regulated in response to the extracellular copper concentration. We show that elevated levels of N 2 O released as a consequence of decreased cellular NosZ activity lead to the bacterium switching from vitamin B 12 -dependent to vitamin B 12 -independent biosynthetic pathways, through the transcriptional modulation of genes controlled by vitamin B 12 riboswitches. This inhibitory effect of N 2 O can be rescued by addition of exogenous vitamin B 12 .denitrification | transcription | NosR | NosC G lobal atmospheric loading of the ozone-depleting greenhouse gas, nitrous oxide (N 2 O), is on the increase (1). Molecule for molecule, its radiative potential is ∼300-fold higher than carbon dioxide (2, 3), comprising ∼9% of global radiative forcing by greenhouse gases (4). In addition, atmospheric N 2 O is stable for ∼120 y. Approximately 70% of anthropogenic N 2 O loading arises from agriculture, mainly from the use of nitrogencontaining fertilizers by soil microbes for dissimilatory purposes. Taken together, these features make N 2 O an important target for mitigation strategies (5).N 2 O is an intermediate in the sequential reduction of nitrate (NO 3 − ) to di-nitrogen (N 2 ), via nitrite (NO 2 − ), nitric oxide (NO), and N 2 O, a process known as denitrification (6). Under certain conditions, the final step in denitrification is dispensed with and N 2 O is released into the atmosphere. One limiting factor in this process is copper (Cu) availability, the metal cofactor required by the N 2 O reductase (NosZ) that destroys N 2 O (5, 7, 8). During Cu-limitation the catalytic capacity of the Nos system may be exceeded by the rate of the preceding reactions that generate N 2 O (i.e., NO 3 − , NO 2 − , and NO reduction) and thus, N 2 O is emitted by denitrifying bacteria (7, 9, 10).Much attention has been given to the cytotoxic properties of NO as a free-radical and oxidant, but N 2 O is often described as a relatively inert intermediate of the nitrogen cycle. However, N 2 O exhibits cytotoxicity, as it is known to bind to and inactivate vitamin B 12 (B 12 ), an essential cellular cofactor in B 12 -dependent enzymes involved in methionine and DNA synthesis (11,12). B 12 also acts as a ligand for B 12 riboswitches that modulate gene expression in the absence of this cofactor (13,14). The possible impact of environmental N 2 O emissions on B 12 metabolism in microbiological communities has largely been ignored. As levels of N 2 O increase in the environment, there is a compelling argument for ...
The enteric bacterium Salmonella enterica serovar Typhimurium is a pathogen that is highly adapted for both intracellular and extracellular survival in a range of oxic and anoxic environments. The cytotoxic radical nitric oxide (NO) is encountered in many of these environments. Protection against NO may involve reductive detoxification in low-oxygen environments, and three enzymes, flavorubredoxin (NorV), flavohaemoglobin (HmpA) and cytochrome c nitrite reductase (NrfA), have been shown to reduce NO in vitro. In this work we determined the role of these three enzymes in NO detoxification by Salmonella by assessing the effects of all eight possible combinations of norV, hmpA and nrfA single, double and triple mutations. The mutant strains were cultured and exposed to NO following either glucose fermentation (when nitrite reductase activity is low), or anaerobic respiration (when nitrite reductase activity is high). Wild-type cultures were more sensitive to the addition of a pulse of NO when grown under fermentative conditions compared with anaerobic respiratory conditions. Analysis of the mutant strains suggested an important additive role for both NorV and NrfA in both environments, since the norV nrfA mutant could not grow after NO addition. The results also suggested a minor role for HmpA in anaerobic detoxification of NO under the two growth conditions, and a larger role for HmpA in aerobic NO detoxification was confirmed. Activity assays and measurements of NO consumption showed that increased nitrite reductase activity correlates with an elevated capacity for NO reduction by intact cells. Taken together, the results reveal a combined role for NorV and NrfA in NO detoxification under anaerobic conditions, and highlight the influence that growth conditions have on the sensitivity to NO of this pathogenic bacterium.
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