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Query: EC:2.7.7.6 (RNA polymerase)
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Seven virulence loci have been identified by Tn5 insertion mutagenesis on the large 230 kb plasmid (pMYSH6000) of Shigella flexneri 2a. In this study, we used Tn10 insertion mutagenesis and identified a novel virulence locus on pMYSH6000 responsible for bacterial spread. Characterization of the invading bacteria of the Tn10 insertion mutants in the epithelial cells revealed that the bacteria were capable of at least some intracellular spreading but not intercellular spreading. Immunoblot analysis of lysates of the Tn10 insertion mutants with a VirG-specific antipeptide antibody revealed diminished levels of the 116 kDa VirG protein. The virG mRNA in the mutants, however, was expressed at the same level as that in the wild type. The DNA region required for the virulence phenotype was localized to a 1.6 kb DNA sequence in the SalI-K fragment on the plasmid, and thus the locus was designated virK. Expression of virK in Escherichia coli using a T7 RNA polymerase-dependent promoter system yielded a 36 kDa protein. The nucleotide sequence of 1642 bp encoding VirK function was determined, and an open reading frame encoding 316 amino acid residues was shown to encode the VirK protein. The virK region was highly conserved among the large virulence plasmids of shigellae and enteroinvasive Escherichia coli. These results suggest that VirK function is an essential virulence determinant for shigellae involved in the expression of virG gene product at post-transcriptional level.
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PMID:Identification and characterization of virK, a virulence-associated large plasmid gene essential for intercellular spreading of Shigella flexneri. 140 77

One of the earliest steps in the pathogenic cycle of the facultative intracellular pathogen Salmonella spp. is the invasion of the cells of the intestinal epithelium. We have previously identified a genetic locus, inv, that allows Salmonella spp. to enter cultured epithelial cells. invA is a member of this locus, and it is the first gene of an operon consisting of at least two additional invasion genes. We have constructed strains carrying nonpolar mutations in invA and examined the individual contribution of this gene to the invasion phenotype of Salmonella typhimurium. Nonpolar S. typhimurium invA mutants were deficient in invasion of cultured epithelial cells although they were fully capable of attaching to the same cells. In addition, unlike wild-type S. typhimurium, invA mutants did not alter the normal architecture of the microvilli of polarized epithelial cells nor did they cause any alterations in the distribution of actin microfilaments of infected cells. The invasion phenotype of invA mutants was readily rescued by wild-type S. typhimurium when cultured epithelial cells were simultaneously infected with both strains. On the contrary, in a similar experiment, the adherent Escherichia coli strain RDEC-1 was not internalized into cultured cells when coinfected with wild-type S. typhimurium. The invA locus was found to be located at about 59 min on the Salmonella chromosome, 7% linked to mutS. The nucleotide sequence of invA showed an open reading frame capable of encoding a polypeptide of 686 amino acids with eight possible membrane-spanning regions and a predicted molecular weight of 75,974. A protein of this size was visualized when invA was expressed in a bacteriophage T7 RNA polymerase-based expression system. The predicted sequence of InvA was found to be homologous to Caulobacter crescentus FlbF, Yersinia LcrD, Shigella flexneri VirH, and E. coli FlhA proteins. These proteins may form part of a family of proteins with a common function, quite possibly the translocation of specific proteins across the bacterial cell membrane.
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PMID:Molecular and functional characterization of the Salmonella invasion gene invA: homology of InvA to members of a new protein family. 162 29

Live Shigella flexneri 2a and Shigella sonnei Phase I vaccine candidate strains with two virulence-reducing markers were constructed through stepwise incorporation of weakly attenuating purine auxotrophy with subsequent rifampicin-resistance (RNA polymerase) mutation to yield optimal attenuation. These vaccine candidate strains showed an unaltered plasmid profile; did not cause keratoconjunctivitis in the Sereny test, while being excreted for a short but still marked period and providing partial protection from wild-strain infection; exhibited for guinea-pig conjunctival epithelia, HeLa cells and rat enterocytes a maintained invasiveness with reduced intracellular multiplication with little, if any, reversible cell damage; and produced, just as their ultrasonic lysates, no exudative reaction in the rabbit gut loop test.
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PMID:Live Shigella flexneri 2a and Shigella sonnei I vaccine candidate strains with two attenuating markers. I. Construction of vaccine candidate strains with retained invasiveness but reduced intracellular multiplication. 218 Feb 30

Transcription of the virB gene, a transcriptional regulator of invasion genes on the large plasmid of Shigella flexneri, is strictly regulated by growth temperature; when bacteria are grown at 37 degrees C, virB transcription is highly activated, while at 30 degrees C the level of virB transcription decreases to less than 5% of that at 37 degrees C. Transcription from the virB promoter is activated by VirF, which is encoded on the same plasmid, in a DNA superhelicity-dependent manner (T. Tobe, M. Yoshikawa, T. Mizuno, and C. Sasakawa, J. Bacteriol. 175:6142-6149, 1993). Here we provide evidence supporting the involvement of negative superhelicity in the thermoregulation of virB transcription. A local negatively supercoiled domain in the virB promoter region was created by activating a divergent transcription from the T7 RNA polymerase-dependent promoter, phi 10, which was placed upstream of the virB promoter in the opposite orientation. Transcription from the virB promoter was activated even at 30 degrees C by induction of divergent transcription. Levels of virB transcription correlated with levels of expressed T7 RNA polymerase. Transcriptional activation of virB by the system depended completely upon VirF function. The level of virB transcription achieved by introducing a negatively supercoiled domain was enough to give rise to expression of invasion capacity at 30 degrees C. These results indicated that the repression of virB transcription at 30 degrees C was caused by a reduction in negative superhelicity around the virB promoter region at 30 degrees C.
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PMID:Thermoregulation of virB transcription in Shigella flexneri by sensing of changes in local DNA superhelicity. 786 May 90

Transcription during the bacteriophage Mu lytic cycle occurs in three phases: early, middle, and late. Previous DNA sequence analysis of the middle operon revealed five potential open reading frames (ORFs) with lengths of 39, 42, 72, 120, and 140 amino acids. The distal 140-amino-acid ORF encodes C, the activator of late transcription. Expression of the middle operon under the control of a T7 promoter and T7 RNA polymerase resulted in production of two polypeptides of 15 (ORF 120) and 16.5 kDa (C). Introduction of a linker containing a translation terminator into ORF120 resulted in the production of a truncated form of the ORF120 polypeptide. When the ORF120 linker mutation and several middle operon deletion mutations were assayed for their effect on Mu growth in Escherichia coli K12, the deletions caused 6- to 22-min delays in lysis, and two resulted in a smaller plaque morphology, but all gave normal plating efficiencies and burst sizes. The plating efficiencies for all the mutants were also similar to that of wild-type Mu on alternate hosts E. coli C, Citrobacter freundii, Shigella sonnei, and Shigella flexneri. These results indicate that, with the exception of C, the middle operon ORFs are not essential for phage development.
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PMID:The bacteriophage Mu middle operon: essential and nonessential functions. 837 43

The RfaH protein controls the transcription of a specialized group of Escherichia coli and Salmonella operons that direct the synthesis, assembly and export of the lipopolysaccharide core, exopolysaccharide, F conjugation pilus and haemolysin toxin. RfaH is a specific regulator of transcript elongation; its loss increases transcription polarity in these operons without affecting initiation from the operon promoters. The operons of the RfaH-dependent regulon contain a short conserved 5' sequence, the ops element, deletion of which increases operon polarity to an extent similar to that caused by loss of RfaH. The ops element is also present upstream of polysaccharide gene clusters of Shigella flexneri, Yersinia enterocolitica, Vibrio cholerae and Klebsiella pneumoniae and the RP4 fertility operon of Pseudomonas aeruginosa, suggesting that this is a widely spread control system. The mechanistic coupling of RfaH and the ops element has been demonstrated in vitro and in vivo, and we suggest that the ops element recruits RfaH and potentially other factors to the RNA polymerase complex, modifying the complex to increase its processivity and allowing transcription to proceed over long distances.
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PMID:RfaH and the ops element, components of a novel system controlling bacterial transcription elongation. 942 23

We have isolated the lysogenic bacteriophage SfII, which mediates glucosylation of Shigella flexneri O-antigen, resulting in expression of the type II antigen. SfII belongs to group A of the Bradley classification and has a genome size of 42.3kb. DNA sequencing of a 4 kb BamHI subclone identified four open reading frames (ORFs), of which only two were found to be necessary for serotype conversion. These genes were named bgt, which encodes a putative bactoprenol glucosyl transferase, and gtrII, encoding the putative type II antigen determining glucosyl transferase. These genes are adjacent to the integrase gene (int) and attachment site (attP), which are highly homologous to those of Salmonella bacteriophage P22. Another ORF encoded a highly hydrophobic protein of 120 amino acids with homologues in Escherichia coli, Salmonella bacteriophage P22 and S. flexneri. Previous studies identified gtrX, the glucosyl transferase gene, of bacteriophage SfX, which also glucosylates the O-antigen specifically. We determined that gtrX-mediated expression of the group 7,8 antigen also requires bgt. This allowed us to identify gtrII as being the serotype antigen II determining glucosyl transferase. Southern hybridization and polymerase chain reaction (PCR) analyses indicated that bgt homologues exist in the genomes of all S. flexneri serotypes and in E. coli K-12, whereas gtrII was only detected in strains of serotype 2. Transposon TnphoA-derived chromosomal mutations of bgt and gtrII in S. flexneri serotype 2a were isolated and characterized. [35S]-methionine labelling and the use of a T7 RNA polymerase expression system identified a protein of 34kDa corresponding to Bgt. However, GtrII, which has a predicted molecular weight of 55 kDa, was not detected. We propose that the function of Bgt is to transfer the glucose residues from the UDP-glucose onto bactoprenol and GtrII then transfers the glucose onto the O-antigen repeat unit at the rhamnose III position. The chromosomal organization of these serotype-converting genes, when compared with their homologues in E. coli K-12 chromosome and the P22 bacteriophage genome, were very similar. This suggests that the regions encode similar functions in these organisms and have a similar evolutionary origin.
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PMID:Mechanism of bacteriophage SfII-mediated serotype conversion in Shigella flexneri. 942 31

Inorganic polyphosphate (poly P) is a chain of tens or many hundreds of phosphate (Pi) residues linked by high-energy phosphoanhydride bonds. Despite inorganic polyphosphate's ubiquity--found in every cell in nature and likely conserved from prebiotic times--this polymer has been given scant attention. Among the reasons for this neglect of poly P have been the lack of sensitive, definitive, and facile analytical methods to assess its concentration in biological sources and the consequent lack of demonstrably important physiological functions. This review focuses on recent advances made possible by the introduction of novel, enzymatically based assays. The isolation and ready availability of Escherichia coli polyphosphate kinase (PPK) that can convert poly P and ADP to ATP and of a yeast exopolyphosphatase that can hydrolyze poly P to Pi, provide highly specific, sensitive, and facile assays adaptable to a high-throughput format. Beyond the reagents afforded by the use of these enzymes, their genes, when identified, mutated, and overexpressed, have offered insights into the physiological functions of poly P. Most notably, studies in E. coli reveal large accumulations of poly P in cellular responses to deficiencies in an amino acid, Pi, or nitrogen or to the stresses of a nutrient downshift or high salt. The ppk mutant, lacking PPK and thus severely deficient in poly P, also fails to express RpoS (a sigma factor for RNA polymerase), the regulatory protein that governs > or = 50 genes responsible for stationary-phase adaptations to resist starvation, heat and oxidant stresses, UV irradiation, etc. Most dramatically, ppk mutants die after only a few days in stationary phase. The high degree of homology of the PPK sequence in many bacteria, including some of the major pathogenic species (e.g. Mycobacterium tuberculosis, Neisseria meningitidis, Helicobacter pylori, Vibrio cholerae, Salmonella typhimurium, Shigella flexneri, Pseudomonas aeruginosa, Bordetella pertussis, and Yersinia pestis), has prompted the knockout of their ppk gene to determine the dependence of virulence on poly P and the potential of PPK as a target for antimicrobial drugs. In yeast and mammalian cells, exo- and endopolyphosphatases have been identified and isolated, but little is known about the synthesis of poly P or its physiologic functions. Whether microbe or human, all species depend on adaptations in the stationary phase, which is truly a dynamic phase of life. Most research is focused on the early and reproductive phases of organisms, which are rather brief intervals of rapid growth. More attention needs to be given to the extensive period of maturity. Survival of microbial species depends on being able to manage in the stationary phase. In view of the universality and complexity of basic biochemical mechanisms, it would be surprising if some of the variety of poly P functions observed in microorganisms did not apply to aspects of human growth and development, to aging, and to the aberrations of disease. Of theoretical interest regarding poly P is its antiquity in prebiotic evolution, which along with its high energy and phosphate content, make it a plausible precursor to RNA, DNA, and proteins. Practical interest in poly P includes many industrial applications, among which is the microbial removal of Pi in aquatic environments.
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PMID:Inorganic polyphosphate: a molecule of many functions. 1087 45

The plasmid-encoded Per regulatory locus of enteropathogenic Escherichia coli (EPEC) is generally considered to consist of three genes, perA, perB and perC. PerA, a member of the AraC-like family of transcriptional regulators, is known to be an activator of its own promoter (autoactivation) as well as of the plasmid-located bfp operon encoding bundle-forming pili, but its role in activation of the chromosomal locus of enterocyte effacement (LEE) pathogenicity island, which confers the property of intimate adherence on EPEC, requires clarification. Here, we show that PerA is also required for activation of the master regulatory LEE operon, LEE1, but that this activation is indirect, being achieved via autoactivation of the per promoter which ensures sufficient production of the PerC protein to activate LEE1. In contrast, PerA-dependent activation of the per and bfp promoters is direct and does not require the other Per proteins, but is modulated by the nucleoid-associated protein H-NS. The closely related VirF regulator from Shigella flexneri cannot substitute for PerA to activate these promoters, despite being able to bind their upstream regions in vitro. PerA can bind the per and bfp promoter fragments to form multiple complexes, while VirF forms only a single complex. Site-directed mutagenesis of the PerA protein suggests that, like VirF, it may use both of its carboxy-terminal helix-turn-helix motifs for DNA interaction, and may also make direct contacts with RNA polymerase. In addition, we have isolated mutations in the poorly characterized amino-terminal domain of PerA which affect its ability to activate gene expression.
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PMID:Direct and indirect transcriptional activation of virulence genes by an AraC-like protein, PerA from enteropathogenic Escherichia coli. 1552 91

Bacteria of Shigella spp. are responsible for shigellosis in humans. They use a type III secretion (TTS) system encoded by a 200 kb virulence plasmid to enter epithelial cells and trigger apoptosis in macrophages. This TTS system comprises a secretion apparatus, translocators and effectors that transit through this apparatus, cytoplasmic chaperones and specific transcription regulators. The TTS apparatus assembled during growth of Shigella flexneri in broth is activated upon contact with epithelial cells. Transcription of approximately 15 genes encoding effectors, including IpaH proteins, is regulated by the TTS apparatus activity and controlled by MxiE, a transcription activator of the AraC family, and IpgC, the chaperone of the translocators IpaB and IpaC. We present evidence that MxiE is produced by a frameshift between a 59-codon open reading frame (ORF) (mxiEa) containing the translation start site and a 214-codon ORF (mxiEb) encoding the DNA binding domain of the protein. The mxiEa encoded N-terminal part of MxiE is required for MxiE function. Frameshifting efficiency was approximately 30% during growth in broth and was not modulated by the activity of secretion or the coactivator IpgC. Frameshifting involves slippage of RNA polymerase during transcription of mxiE, which results in the incorporation of one additional nucleotide in the mRNA and places mxiEa and mxiEb in the same reading frame. Frameshifting might represent an additional means of controlling gene expression under specific environmental conditions.
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PMID:Frameshifting by transcriptional slippage is involved in production of MxiE, the transcription activator regulated by the activity of the type III secretion apparatus in Shigella flexneri. 1577 90

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