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Query: UNIPROT:P51532 (
transcriptional activator
)
6,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The Proteus mirabilis and plasmid-encoded
urease
loci contain seven contiguous structural and accessory genes (ureDABCEFG) and the divergently transcribed ureR, which codes for an AraC-like
transcriptional activator
. Previously, it was shown that the plasmid-encoded ureR to ureD intergenic region contained divergent promoters (ureRp and ureDp). Transcription from these promoters required both the effector molecule urea and the activator protein UreR. In this report, we demonstrate that the P. mirabilis
urease
gene cluster contains similar divergent urea- and UreR-dependent promoters. The ureR gene products from either
urease
locus were able to activate transcription at both the plasmid-encoded and P. mirabilis promoters. The minimal concentration of urea required to activate transcription at ureRp or ureDp from either gene cluster was approximately 4 mM. The transcriptional start sites for the plasmid-encoded and P. mirabilis divergent promoters were similar in an Escherichia coli DH5 alpha background, as determined by primer-extension analysis. However, in P. mirabilis HI4320, transcription of ureR initiated predominately at an alternative site. Physical mapping and inhibition studies were used to localize the UreR-binding sites within the plasmid-encoded ureRp and ureDp intergenic sequences to regions of 68 bp and 86 bp, respectively. Gel shift analysis demonstrated that UreR bound to a 135 bp fragment in the approximate centre of the plasmid-encoded ureR to ureD intergenic region. The results presented here suggest that the P. mirabilis and plasmid-encoded
urease
gene clusters utilize similar mechanisms of transcriptional activation in response to urea.
...
PMID:Activation of transcription at divergent urea-dependent promoters by the urease gene regulator UreR. 886 86
Proteus mirabilis, a cause of complicated urinary tract infection, expresses
urease
when exposed to urea. While it is recognized that the positive
transcriptional activator
UreR induces gene expression, the levels of expression of the enzyme during experimental infection are not known. To investigate in vivo expression of P. mirabilis
urease
, the gene encoding green fluorescent protein (GFP) was used to construct reporter fusions. Translational fusions of
urease
accessory gene ureD, which is preceded by a urea-inducible promoter, were made with gfp (modified to express S65T/V68L/S72A [B. P. Cormack et al. Gene 173:33-38, 1996]). Constructs were confirmed by sequencing of the fusion junctions. UreD-GFP fusion protein was induced by urea in both Escherichia coli DH5alpha and P. mirabilis HI4320. By using Western blotting with antiserum raised against GFP, expression level was shown to correlate with urea concentration (tested from 0 to 500 mM), with highest induction at 200 to 500 mM urea. Fluorescent E. coli and P. mirabilis bacteria were observed by fluorescence microscopy following urea induction, and the fluorescence intensity of GFP in cell lysates was measured by spectrophotofluorimetry. P. mirabilis HI4320 carrying the UreD-GFP fusion plasmid was transurethrally inoculated into the bladders of CBA mice. One week postchallenge, fluorescent bacteria were detected in thin sections of both bladder and kidney samples; the fluorescence intensity of bacteria in bladder tissue was higher than that in the kidney. Kidneys were primarily infected with single-cell-form fluorescent bacteria, while aggregated bacterial clusters were observed in the bladder. Elongated swarmer cells were only rarely observed. These observations demonstrate that
urease
is expressed in vivo and that using GFP as a reporter protein is a viable approach to investigate in vivo expression of P. mirabilis virulence genes in experimental urinary tract infection.
...
PMID:Use of green fluorescent protein to assess urease gene expression by uropathogenic Proteus mirabilis during experimental ascending urinary tract infection. 942 75
Bordetella bronchiseptica is a common ureolytic mammalian respiratory pathogen. The
urease
operon of this organism is encoded within an 8.9 kb DNA fragment which contains the structural genes (ureA, ureB and ureC) and accessory genes (ureD and ureG) homologous to other
urease
genes. Uniquely, the ureE and ureF genes are fused to form a hybrid protein, UreEF, which may result in tighter coordination of the putative functions of the individual accessory genes, nickel donation to the
urease
active site, and prevention of nickel incorporation until correct formation of the active site, respectively. The operon contains an additional open reading frame, UreJ, found only also in the Alcaligenes eutrophus
urease
operon. UreJ is also 37% homologous with HupE from Rhizobium leguminosarum bv. viciae, and may potentially be involved in nickel transport. A
transcriptional activator
, designated Bordetella bronchiseptica
urease
regulator (BbuR), is located directly upstream and in the opposite orientation to the
urease
operon. BbuR shares homology with members of the LysR regulatory protein family. LysR proteins have been shown to regulate
urease
in Klebsiella aerogenes (NAC), and catalase in Escherichia coli (OxyR), which offers the intracellular bacterium protection from phagolysosome damage. A putative BbuR binding site (5'-ATA-N9-TAT-3'), identical to the NAC-binding consensus sequence, was found 27 bp upstream of the
urease
promoter in B. bronchiseptica. We hypothesise that BbuR controls
urease
expression which is involved in protection of intracellular B. bronchiseptica from phagolysosomal damage. Comparison of the
urease
promoter regions of B. bronchiseptica, Bordetella parapertussis ATCC15311 and the
urease
-negative strain B. pertussis Tohama I revealed no differences in the ureD open reading frame between each species. A cluster of mutations in both B. pertussis and B. parapertussis was found upstream of the
urease
promoter, in a region proximal to the putative bbuR promoter. The inability of B. pertussis to produce
urease
may therefore reflect mutations in regulatory elements, and not mutations in the
urease
locus itself.
...
PMID:Characterisation of the urease gene cluster in Bordetella bronchiseptica. 952 76
The closely related Proteus mirabilis and Enterobacterlaceae plasmid-encoded
urease
genes are positively regulated by the AraC-like
transcriptional activator
UreR. In the presence of the effector molecule urea, UreR promotes transcription of ureD, the initial gene in the
urease
operon, and increases transcription of the divergently transcribed ureR. Here, we identify UreR-specific binding sites in the ureRp-ureDp intergenic regions. Recombinant UreR (rUreR) was expressed and purified, and gel shift and DNase I protection assays were performed with this protein. These analyses indicated that there are two distinct rUreR binding sites in both the plasmid-encoded and P. mirabilis ureRp-ureDp intergenic regions. A consensus binding site of TA/GT/CA/TT/GC/TTA/TT/AATTG was predicted from the DNase I protection assays. Although rUreR bound to the specific DNA binding site in both the presence and the absence of urea, the dissociation rate constant k-1 of the rUreR-DNA complex interaction was measurably different when urea was present. In the absence of urea, the dissociation of the protein-DNA complexes, for both ureRp and ureDp, was complete at the earliest time point, and it was not possible to determine a rate. In the presence of urea, dissociation was measurable with a k-1 for the rUreR-ureRp interaction of 1.2 +/- 0.2 x 10(-2) s-1 and a k-1 for the rUreR-ureDp interaction of 2.6 +/- 0.1 x 10(-3) s-1. This corresponds to a half-life of the ureRp-rUreR interaction of 58 s, and a half-life of the ureDp-rUreR interaction of 4 min 26 s. A model describing a potential role for urea in the activation of these promoters is proposed.
...
PMID:Identification of UreR binding sites in the Enterobacteriaceae plasmid-encoded and Proteus mirabilis urease gene operons. 1020 Sep 62
Expression of Proteus mirabilis
urease
is governed by UreR, an AraC-like positive
transcriptional activator
. A poly(A) tract nucleotide sequence, consisting of A(6)TA(2)CA(2)TGGTA(5)GA(6)TGA(5), is located 16 bp upstream of the sigma(70)-like ureR promoter P2. Since poly(A) tracts of DNA serve as binding sites for the gene repressor histone-like nucleoid structuring protein (H-NS), we measured beta-galactosidase activity of wild-type Escherichia coli MC4100 (H-NS(+)) and its isogenic derivative ATM121 (hns::Tn10) (H-NS(-)) harboring a ureR-lacZ operon fusion plasmid (pLC9801). beta-Galactosidase activity in the H-NS(-) host strain was constitutive and sevenfold greater (P < 0.0001) than that in the H-NS(+) host. A recombinant plasmid containing cloned P. mirabilis hns was able to complement and restore repression of the ureR promoter in the H-NS(-) host when provided in trans. Deletion of the poly(A) tract nucleotide sequence from pLC9801 resulted in an increase in beta-galactosidase activity in the H-NS(+) host to nearly the same levels as that observed for wild-type pLC9801 harbored by the H-NS(-) host. Urease activity in strains harboring the recombinant plasmid pMID1010 (encoding the entire
urease
gene cluster of P. mirabilis) was equivalent in both the H-NS(-) background and the H-NS(+) background in the presence of urea but was eightfold greater (P = 0.0001) in the H-NS(-) background in the absence of urea. We conclude that H-NS represses ureR expression in the absence of urea induction.
...
PMID:H-NS is a repressor of the Proteus mirabilis urease transcriptional activator gene ureR. 1076 73
The hydrolysis of urea by ureases of oral bacteria in dental plaque can cause a considerable increase in plaque pH, which can inhibit the development of dental caries. There is also indirect evidence that urea metabolism may promote the formation of calculus and that ammonia release from urea could exacerbate periodontal diseases. Actinomyces naeslundii, an early colonizer of the oral cavity and a numerically significant plaque constituent, demonstrates comparatively low levels of
urease
activity on isolation, so this organism has not been considered a major contributor to total oral
urease
activity. In this study it was observed that
urease
activity and
urease
-specific mRNA levels in A. naeslundii WVU45 can increase up to 50-fold during growth under nitrogen-limiting conditions. Using primer extension analysis, a putative, proximal, nitrogen-regulated promoter of the A. naeslundii
urease
gene cluster was identified. The functionality and nitrogen responsiveness of this promoter were confirmed using reporter gene fusions and 5' deletion analysis. The data indicated that regulation of
urease
expression by nitrogen availability in A. naeslundii may require a positive
transcriptional activator
. Plaque bacteria may experience nitrogen limitation when carbohydrates are present in excess. Therefore, based on the results of this study and in contrast to previous beliefs, strains of A. naeslundii may have the potential to be significant contributors to total plaque ureolysis, particularly during periods when there is an increased risk for caries development.
...
PMID:Analysis of urease expression in Actinomyces naeslundii WVU45. 1108 80
Identification of the environmental triggers involved in the expression of virulence genes is a fundamental objective in studies of bacterial pathogens. For uropathogens, urea, found in the urinary tract at concentrations of up to 500 mm, functions as an environmental signal. Urea freely diffuses into the bacterium Providencia stuartii and activates UreR, a member of the AraC family of transcriptional activators. Active UreR promotes transcription of virulence-associated
urease
genes and alerts the organisms of its immediate milieu. Thus, the UreR.urea complex has a dual role, acting as both a
transcriptional activator
as well as an environmental sensor. Here, we describe the molecular events associated with activation of gene expression by urea-bound UreR. The K(d) of the urea.UreR binding reaction was measured as 0.2 mm by fluorescence quenching assays, and the shape of the binding curve indicated a single specific urea-binding site on UreR. Histidine residues are critical for urea binding in
urease
, and therefore to identify the urea-binding site in UreR, five mutant UreR forms were generated with histidine to alanine substitutions. Two of the mutants (UreR(c)) exhibited a constitutive phenotype by both activating transcription and binding to DNA with an increased affinity in the absence of urea. The UreR(c) bound urea with an affinity similar to that of wild-type UreR. We concluded, therefore, that the mutations resulting in constitutive activity were not involved in the UreR.urea interaction. UreR was activated, then, either by binding urea or by histidine to alanine substitutions at one of two positions. Circular dichroism indicated little change in the structure of UreR when activated, and size-exclusion chromatography demonstrated that both rUreR and rUreR(c) were dimers in both the presence and absence of urea. Thus, the structural changes associated with activation are subtle.
...
PMID:Urea-dependent signal transduction by the virulence regulator UreR. 1214 87
Helicobacter pylori and Proteus mirabilis ureases are nickel-requiring metallo-enzymes that hydrolyse urea to NH3 and CO2. In both H. pylori and in an Escherichia coli model of H. pylori
urease
activity, a high affinity nickel transporter, NixA, is required for optimal
urease
activity, whereas the urea-dependent UreR positive
transcriptional activator
governs optimal
urease
expression in P. mirabilis. The H. pylori flbA gene is a flagellar biosynthesis and regulatory gene that modulates
urease
activity in the E. coli model of H. pylori
urease
activity. All flbA mutants of eight strains of H. pylori were non-motile and five had a strain-dependent alteration in
urease
activity. The flbA gene decreased
urease
activity 15-fold when expressed in E. coli containing the H. pylori
urease
locus and the nixA gene; this was reversed by disruption of flbA. The flbA gene decreased nixA transcription. flbA also decreased
urease
activity three-fold in E. coli containing the P. mirabilis
urease
locus in a urea- and UreR-dependent fashion. Here the flbA gene repressed the P. mirabilis
urease
promoter. Thus, FlbA decreased
urease
activity of both H. pylori and P. mirabilis, but through distinct mechanisms. H. pylori wild-type strain SS1 colonised gerbils at a mean of 5.4 x 10(6) cfu/g of antrum and caused chronic gastritis and lesions in the antrum. In contrast, the flbA mutant did not colonise five of six gerbils and caused no lesions, indicating that motility mediated by flbA was required for colonisation. Because FlbA regulates flagellar biosynthesis and secretion, as well as forming a structural component of the flagellar secretion apparatus, two seemingly unrelated virulence attributes, motility and
urease
, may be coupled in H. pylori and P. mirabilis and possibly also in other motile, ureolytic bacteria.
...
PMID:The Helicobacter pylori flbA flagellar biosynthesis and regulatory gene is required for motility and virulence and modulates urease of H. pylori and Proteus mirabilis. 1244 80
Proteus mirabilis, a cause of catheter-associated urinary tract infection, relies on several virulence factors to colonize the urinary tract. Among these,
urease
contributes to the development of urinary stones resulting from the increase in local pH due to
urease
-mediated hydrolysis of urea to NH(3) and CO(2). UreR, an AraC-like
transcriptional activator
, activates transcription of the genes encoding the
urease
subunits and accessory proteins (ureDABCEFG) in the presence of urea. UreR also initiates transcription of its own gene in a urea-inducible manner by binding to the intergenic region between ureR and ureD. The intergenic region contains poly(A) tracts that appear to be the target of H-NS. It has been shown that Escherichia coli and P. mirabilis H-NS acts to repress transcription of ureR in an E. coli model system. It was hypothesized that H-NS represses
urease
gene expression in the absence of UreR and urea by binding to the intergenic region. To demonstrate this the P. mirabilis hns gene was cloned and the 15.6 kDa H-NS was overexpressed and purified as a myc-His tail fusion. Using a gel shift assay, purified H-NS-myc-His bound preferentially to a 609 bp DNA fragment containing the entire ureR-ureD intergenic region. H-NS and UreR were able to displace each other from the ureR-ureD intergenic region. Circular permutation analysis revealed that the intergenic region is bent. Moreover, H-NS recognizes this curvature, binds the DNA fragment and induces further bending of the DNA as shown by a circular ligation assay. The effects of H-NS, urea and temperature (25 vs 37 degrees C) on
urease
expression were shown in E. coli containing an hns knockout and P. mirabilis where expression was increased at 37 degrees C. Increased transcription from p(ureR) was seen in the E. coli hns knockout when temperature was increased from 25 to 37 degrees C. These findings suggest H-NS and UreR differentially regulate
urease
in a negative and positive manner, respectively.
...
PMID:Differential regulation of the Proteus mirabilis urease gene cluster by UreR and H-NS. 1466 72
