Maya Elgrably‐Weiss scite author profile

The emergence of pathogenic strains of enteric bacteria and their adaptation to unique niches are associated with the acquisition of foreign DNA segments termed ‘genetic islands’. We explored these islands for the occurrence of small RNA (sRNA) encoding genes. Previous systematic screens for enteric bacteria sRNAs were mainly carried out using the laboratory strain Escherichia coli K12, leading to the discovery of ∼80 new sRNA genes. These searches were based on conservation within closely related members of enteric bacteria and thus, sRNAs, unique to pathogenic strains were excluded. Here we describe the identification and characterization of 19 novel unique sRNA genes encoded within the ‘genetic islands’ of the virulent strain Salmonella typhimurium. We show that the expression of many of the island-encoded genes is associated with stress conditions and stationary phase. Several of these sRNA genes are induced when Salmonella resides within macrophages. One sRNA, IsrJ, was further examined and found to affect the translocation efficiency of virulence-associated effector proteins into nonphagocytic cells. In addition, we report that unlike the majority of the E. coli sRNAs that are trans regulators, many of the island-encoded sRNAs affect the expression of cis-encoded genes. Our study suggests that the island encoded sRNA genes play an important role within the network that regulates bacterial adaptation to environmental changes and stress conditions and thus controls virulence.

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A pH-responsive riboregulator

Nechooshtan

Elgrably‐Weiss²,

Sheaffer³

et al. 2009

Genes Dev.

127

118

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The locus alx, which encodes a putative transporter, was discovered previously in a screen for genes induced under extreme alkaline conditions. Here we show that the RNA region preceding the alx ORF acts as a pH-responsive element, which, in response to high pH, leads to an increase in alx expression. Under normal growth conditions this RNA region forms a translationally inactive structure, but when exposed to high pH, a translationally active structure is formed to produce Alx. Formation of the active structure occurs while transcription is in progress under alkaline conditions and involves pausing of RNA polymerase at two distinct sites. Alkali increases the longevity of pausing at these sites and thereby interferes with formation of the inactive structure and promotes folding of the active one. The alx locus represents the first example of a pH-responsive riboregulator of gene expression, introducing a novel regulatory mechanism that involves RNA folding dynamics driven by pH.[Keywords: RNA regulator; transcriptional pausing; alkaline conditions; translation control] Supplemental material is available at http://www.genesdev.org.

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Identification of an Escherichia coli Operon Required for Formation of the O-Antigen Capsule

et al. 2005

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Escherichia coli produces polysaccharide capsules that, based on their mechanisms of synthesis and assembly, have been classified into four groups. The group 4 capsule (G4C) polysaccharide is frequently identical to that of the cognate lipopolysaccharide O side chain and has, therefore, also been termed the O-antigen capsule. The genes involved in the assembly of the group 1, 2, and 3 capsules have been described, but those required for G4C assembly remained obscure. We found that enteropathogenic E. coli (EPEC) produces G4C, and we identified an operon containing seven genes, ymcD, ymcC, ymcB, ymcA, yccZ, etp, and etk, which are required for formation of the capsule. The encoded proteins appear to constitute a polysaccharide secretion system. The G4C operon is absent from the genomes of enteroaggregative E. coli and uropathogenic E. coli. E. coli K-12 contains the G4C operon but does not express it, because of the presence of IS1 at its promoter region. In contrast, EPEC, enterohemorrhagic E. coli, and Shigella species possess an intact G4C operon.

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Escherichia coli response to hydrogen peroxide: a role for DNA supercoiling, Topoisomerase I and Fis

Weinstein-Fischer

Elgrably‐Weiss

Altuvia³

2000

Molecular Microbiology

107

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SummaryBacterial cells respond to the deleterious effects of reactive oxygen species by inducing the expression of antioxidant defence genes. Here we show that treatment with hydrogen peroxide leads to a transient decrease in DNA negative supercoiling. We also report that hydrogen peroxide activates topA P1 promoter expression. The peroxide-dependent topA P1 activation is independent of oxyR, but is mediated by Fis. This nucleoid-associated protein binds to the promoter region of topA. We also show that a fis deficient mutant strain is extremely sensitive to hydrogen peroxide. Our results suggest that topA activation by Fis is an important component of the Escherichia coli response to oxidative stress.

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Characterization of Escherichia coli DNA Lesions Generated within J774 Macrophages

Schlosser-Silverman¹,

Elgrably‐Weiss²,

Rosenshine³

et al. 2000

J Bacteriol

100

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Macrophages are armed with multiple oxygen-dependent and -independent bactericidal properties. However, the respiratory burst, generating reactive oxygen species, is believed to be a major cause of bacterial killing. We exploited the susceptibility of Escherichia coli in macrophages to characterize the effects of the respiratory burst on intracellular bacteria. We show that E. coli strains recovered from J774 macrophages exhibit high rates of mutations. We report that the DNA damage generated inside macrophages includes DNA strand breaks and the modification 8-oxo-2-deoxyguanosine, which are typical oxidative lesions. Interestingly, we found that under these conditions, early in the infection the majority of E. coli cells are viable but gene expression is inhibited. Our findings demonstrate that macrophages can cause severe DNA damage to intracellular bacteria. Our results also suggest that protection against the macrophage-induced DNA damage is an important component of the bacterial defense mechanism within macrophages.Reactive oxygen intermediates can damage proteins, nucleic acids, and cell membranes and have been implicated in cancer, aging, and numerous degenerative diseases. To counter oxidative stress, both prokaryotic and eukaryotic cells maintain inducible defense systems to detoxify the oxidants and to repair the damage. The antioxidant defense systems have been best characterized in Escherichia coli and Salmonella enterica serovar Typhimurium, in which the OxyR and SoxR transcription factors activate genes to protect against H 2 O 2 and O 2 ⅐Ϫ , respectively (reviewed in reference 28).While cells of aerobic organisms generate deleterious reactive oxygen metabolites under normal physiological conditions, stimulated macrophages generate reactive oxygen and nitrogen species as a defense mechanism during infection. Macrophages are armed with multiple oxygen-dependent and -independent bactericidal properties (9). However, the respiratory burst, which generates reactive oxygen and nitrogen species, is believed to be a major cause of bacterial killing. In chronic granulomatous disease, the neutrophils are incapable of producing the respiratory burst, and individuals with chronic granulomatous disease have high rates of mortality due to bacterial infections (20, 23). The deleterious effects of reactive oxygen and nitrogen species have been demonstrated with bacterial cells in culture in numerous studies (28). However, the toxic effects of these reactive species have not been characterized in phagocytosed bacteria. Given that S. enterica serovar Typhimurium recombination-deficient (recA and recBC) mutants showed attenuated virulence in mice and increased sensitivity in macrophages, DNA damage might be an important consequence of the activities inside macrophages (4, 26). In addition, it was shown that human peripheral phagocytes have some mutagenic activity against S. enterica serovar Typhimurium while phagocytes from patients with chronic granulomatous disease do not (32). Therefore, we examined the macropha...

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