Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:6.3.4.6 (
urease
)
7,490
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The
NAC
(nitrogen assimilation control) protein from Klebsiella aerogenes is a LysR-like regulator for transcription of several operons involved in nitrogen metabolism, and couples the transcription of these sigma 70-dependent operons to regulation by the sigma 54-dependent NTR system.
NAC
activates expression of operons (e.g. histidine utilization, hut), allowing use of poor nitrogen sources, and represses expression of operons (e.g. glutamate dehydrogenase, gdh) allowing assimilation of the preferred nitrogen source, ammonium.
NAC
is both necessary and sufficient to activate transcription, but the expression of the nac gene is totally dependent on the central nitrogen regulatory system (NTR) and RNA polymerase carrying the sigma 54 sigma factor (RNAP sigma 54). Nitrogen starvation signals the NTR system to transcribe nac, and
NAC
activates the transcription of hut, put (proline utilization), and
urease
.
NAC
does not affect the transcription of RNAP sigma 54-dependent operons like ginA or nifLA, which respond directly to the NTR system, but activates transcription of RNAP sigma 70-dependent operons. Thus
NAC
acts as a bridge between RNAP sigma 70-dependent operons like hut and the RNAP sigma 54-dependent NTR system. The activation of operons like hut by
NAC
in response to nitrogen starvation is at least superficially similar to their activation by CAP-cAMP in response to carbon and energy starvation.
...
PMID:The role of the NAC protein in the nitrogen regulation of Klebsiella aerogenes. 166 20
In Klebsiella aerogenes, the formation of a large number of enzymes responds to the quality and quantity of the nitrogen source provided in the growth medium, and this regulation requires the action of the nitrogen regulatory (NTR) system in every case known. Nitrogen regulation of several operons requires not only the NTR system, but also
NAC
, the product of the nac gene, raising the question of whether the role of
NAC
is to activate operons directly or by modifying the specificity of the NTR system. We isolated an insertion of the transposon Tn5tac1 which puts nac gene expression under the control of the IPTG-inducible tac promoter rather than the nitrogen-responsive nac promoter. When IPTG was present, cells carrying the tac-nac fusion activated
NAC
-dependent operons and repressed
NAC
-repressible operons independent of the nitrogen supply and even in the absence of an active NTR system. Thus,
NAC
is sufficient to regulate operons like hut (encoding histidase) and gdh (encoding glutamate dehydrogenase), confirming the model that the NTR system activates nac expression and
NAC
activates hut and represses gdh. Activation of
urease
formation occurred at a lower level of
NAC
than that required for glutamate dehydrogenase repression, and activation of histidase formation required still more
NAC
.
...
PMID:The product of the Klebsiella aerogenes nac (nitrogen assimilation control) gene is sufficient for activation of the hut operons and repression of the gdh operon. 845 54
Synthesis of
urease
by Klebsiella species is known to be induced when the nitrogen source of the growth medium is limiting, suggesting that
urease
gene expression is controlled by the nitrogen regulatory (ntr) system. This study showed that K. pneumoniae with mutations in either ntrA or ntrC, two integral components of the ntr system, were phenotypically
urease
-negative. These mutants could be complemented back to a
urease
positive phenotype with recombinant plasmids encoding the corresponding ntr gene. A series of ure-lacZYA transcriptional fusions, in conjunction with primer extension analysis, identified a DNA region that encoded a nitrogen-regulated promoter. This promoter region controlled transcription of ureD, the first gene in the Klebsiella pneumoniae
urease
gene cluster, and ureA, a gene that resides immediately downstream of ureD. A high level of transcription from the ureD promoter required
NAC
, a recently characterized member of the nitrogen regulatory cascade.
NAC
is a Lys R-like transcriptional regulator that can act at sigma 70 promoters; expression from nac itself is dependent upon NTRA. Therefore, expression of K. pneumoniae
urease
was dependent upon the nitrogen regulatory cascade, and transcription of at least two
urease
genes was from a promoter that was positively regulated by
NAC
.
...
PMID:Identification of a nitrogen-regulated promoter controlling expression of Klebsiella pneumoniae urease genes. 849 92
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
Klebsiella pneumoniae can use urea as the sole source of nitrogen, thanks to a
urease
encoded by the ureDABCEFG operon. Expression of this operon is independent of urea and is regulated by the supply of nitrogen in the growth medium. When cells were growth rate limited for nitrogen, the specific activity of
urease
was about 70 times higher than that in cells grown under conditions of excess nitrogen. Much of this nitrogen regulation of
urease
formation depended on the nitrogen regulatory system acting through the nitrogen assimilation control protein,
NAC
. In a strain deleted for the nac gene, nitrogen limitation resulted in only a 7-fold increase in the specific activity of
urease
, in contrast to the 70-fold increase seen in that of the wild type. The ure operon was transcribed from two promoters. The proximal promoter (P1) had an absolute requirement for
NAC
; little or no transcription was seen in the absence of
NAC
. The distal promoter (P2) was independent of
NAC
, but its activity increased about threefold when the growth rate of the cells was limited by the nitrogen source. Transcriptional regulation of P1 and P2 accounted for most of the changes in
urease
activity seen under various nitrogen conditions. However, when transcription of ureDABCEFG was less than 20% of its maximum, the amount of active
urease
formed per transcript of ure decreased almost linearly with decreasing transcription. This may reflect a defect in the assembly of active
urease
and accounted for as much as a threefold activity difference under the conditions tested here. Thus, the ure operon was transcribed from a
NAC
-independent promoter (P2) and the most strongly
NAC
-dependent promoter known (P1). Most of the regulation of
urease
formation was transcriptional, but when ure transcription was low, assembly of active
urease
also was defective.
...
PMID:Complex regulation of urease formation from the two promoters of the ure operon of Klebsiella pneumoniae. 1772 Jul 85
