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Enzyme
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Enzyme
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Query: EC:3.5.1.5 (
urease
)
7,257
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Acidic media trigger cytoplasmic
urease
activity of the unique human gastric pathogen Helicobacter pylori. Deletion of ureI prevents this activation of cytoplasmic
urease
that is essential for bacterial acid resistance. UreI is an inner membrane protein with six transmembrane segments as shown by in vitro transcription/translation and membrane separation. Expression of UreI in Xenopus oocytes results in acid-stimulated urea uptake, with a pH profile similar to activation of cytoplasmic
urease
. Mutation of periplasmic
histidine
123 abolishes stimulation. UreI-mediated transport is urea specific, passive, nonsaturable, nonelectrogenic, and temperature independent. UreI functions as a H+-gated urea channel regulating cytoplasmic
urease
that is essential for gastric survival and colonization.
...
PMID:A H+-gated urea channel: the link between Helicobacter pylori urease and gastric colonization. 1064 49
Mutation in Eu3 eliminates activity of both soybean ureases, the embryo-specific (encoded by Eu1) and the tissue-ubiquitous (encoded by Eu4). eu3-e1 is a completely recessive null allele. Eu3-e3 is a semi-dominant specifying 0.1% wild-type
urease
activity in the homozygous state and 5-10% as a heterozygote (Meyer-Bothling et al. 1987). Antibodies to plant UreG, a homologue of the bacterial
urease
accessory protein, revealed a 32 kDa protein (p32) in embryos of the Eu3/Eu3 precursor genotype. p32 is identical to UreG by the criteria of size, antigenicity, and its ability to bind Ni2+, a trait expected from the deduced
histidine
-rich N-terminus of UreG. UreG was absent in eu3-e1/eu3-e1, and lack of UreG co-segregated with eu3-e1. Eu3-e3 specified a UreG transcript which coded valine in place of alanine at residue 142 (A142V) confirming thatEu3 encodes UreG, which is renamed Eu3. Eu3 (A142V) retained Ni-binding ability. Eu3 is directly involved in
urease
activation, since anti-Eu3 (UreG) antibodies inhibited the in vitro activation of
urease
. Eu1 (embryo
urease
) and Eu3 accumulated in parallel in the developing embryo. The presence of Eu1 was not necessary for the high embryonic level of Eu3. However, the presence of Eu3 appeared to be important for accumulation of Eu1, perhaps by stabilizing it by Ni insertion. At the level of sensitivity employed Eu3 was detected in crude extracts of embryos but not non-embryonic tissues which have 1/500th the embryo
urease
activity. Functional Eu3, however, is necessary for activation of the ubiquitous
urease
in non-embryonic tissues.
...
PMID:The soybean Eu3 gene encodes an Ni-binding protein necessary for urease activity. 1065 50
The
urease
accessory protein encoded by ureE from Klebsiella aerogenes is proposed to deliver Ni(II) to the
urease
apoprotein during enzyme activation. Native UreE possesses a
histidine
-rich region at its carboxyl terminus that binds several equivalents of Ni(2+); however, a truncated form of this protein (H144*UreE) binds only 2 Ni(2+) per dimer and is functionally active (Brayman, T. G., and Hausinger, R. P. (1996) J. Bacteriol. 178, 5410-5416). The
urease
activation kinetics were studied in vivo by monitoring the development of
urease
activity upon adding Ni(2+) to spectinomycin-treated Escherichia coli cells that expressed the complete K. aerogenes
urease
gene cluster with altered forms of ureE. Site-specific alterations of H144*UreE decrease the rate of in vivo
urease
activation, with the most dramatic changes observed for the H96A, H110A, D111A, and H112A substitutions. Notably,
urease
activity in cells producing H96A/H144*UreE was lower than cells containing a ureE deletion. Prior studies had shown that H110A and H112A variants each bound a single Ni(2+) per dimer with elevated K(d) values compared with control H144*UreE, whereas the H96A and D111A variants bound 2 Ni(2+) per dimer with unperturbed K(d) values (Colpas, G. J., Brayman, T. G., Ming, L.-J., and Hausinger, R. P. (1999) Biochemistry 38, 4078-4088). To understand why cells containing the latter two proteins showed reduced rates of
urease
activation, we characterized their metal binding/dissociation kinetics and compared the results to those obtained for H144*UreE. The truncated protein was shown to sequentially bind two Ni(2+) with k(1) approximately 18 and k(2) approximately 100 M(-1) s(-1), and with dissociation rates k(-1) approximately 3 x 10(-3) and k(-2) approximately 10(-4) s(-1). Similar apparent rates of binding and dissociation were noted for the two mutant proteins, suggesting that altered H144*UreE interactions with Ni(2+) do not account for the changes in cellular
urease
activation. These conclusions are further supported by in vitro experiments demonstrating that addition of H144*UreE to
urease
apoprotein activation mixtures inhibited the rate and extent of
urease
formation. Our results highlight the importance of other
urease
accessory proteins in assisting UreE-dependent
urease
maturation.
...
PMID:In vivo and in vitro kinetics of metal transfer by the Klebsiella aerogenes urease nickel metallochaperone, UreE. 1075 63
The activation of the nickel metalloenzyme
urease
is a complex process. In bacteria, several
urease
accessory proteins are essential for incorporation of nickel into the active centre of
urease
. Comparatively little is known about the activation process and the proteins involved in plants. We cloned five different cDNAs encoding isoforms of
urease
accessory protein G (ureG) in potato. The 5'-coding region of these cDNAs is highly polymorphic within Solanum tuberosum ssp. tuberosum, containing mainly a simple sequence repeat encoding
histidine
and aspartate. Mapping on an ultrahigh-density map of the potato genome and Southern blot analysis showed that the isoforms arise from allelic differences of a single-copy gene which was located on chromosome 2. Expression analysis at the mRNA and protein levels indicated the presence of ureG in almost all tissues examined, consistent with the ubiquitous expression of
urease
. An attempt to correlate
urease
activity with ureG expression levels in different tissues was made. Allelic copies of ureG were expressed in a tissue-specific manner. UreG from potato and the Klebsiella aerogenes
urease
operon defective in bacterial ureG were co-expressed in Escherichia coli. The plant gene complements the K. aerogenes ureG mutation, demonstrating that it encodes a
urease
accessory protein and indicating a structural conservation between the plant and the bacterial
urease
activation complexes.
...
PMID:Functional characterisation of urease accessory protein G (ureG) from potato. 1128 8
Helicobacter pylori (Hp) and Streptococcus salivarius (Ss) require intrabacterial
urease
for acid resistance and express a urea channel, UreI. The presence of UreI was shown to increase urea permeability approximately 300-fold over that of a non-polar ureI deletion mutant. Expression of SsUreI in Xenopus oocytes increased urea uptake pH independently, whereas HpUreI shows an acidic pH dependence, half-maximal at pH 6.0. Mutagenesis of all histidines, aspartates, glutamates and the lysine in the periplasmic domain of HpUreI showed that
His
-123,
His
-131, Asp-129, Asp-140, Glu-138 and Lys-132 in the second periplasmic loop (PL2) and
His
-193 in the C-terminus (Ct) were important for activation of transport. With the exception of a lysine that was shown to substitute for
His
-193 in HpUreI, these charged amino acids are absent in SsUreI. A chimera in which PL1 of HpUreI was replaced by PL1 of SsUreI retained activity at acidic pH and gained partial activity at neutral pH. Exchange of PL2 inactivated transport, whereas exchange of Ct had no effect. Chimeras, in which either PL1 or PL2 of HpUreI replaced those of SsUreI, retained wild-type transport, but replacement of the Ct or both loops inactivated transport. PL1 appears to be important for restricting transport through HpUreI at neutral pH, whereas protonation of three histidines in PL2 and Ct and the presence of three dicarboxylic amino acids in PL2 appears to be necessary to activate HpUreI at acidic pH.
...
PMID:Sites of pH regulation of the urea channel of Helicobacter pylori. 1144 25
Proteus mirabilis
urease
catalyzes the hydrolysis of urea to CO(2) and NH(3), resulting in urinary stone formation in individuals with complicated urinary tract infections. UreR, a member of the AraC family, activates transcription of the genes encoding
urease
enzyme subunits and accessory proteins, ureDABCEFG, as well as its own transcription in the presence of urea. Based on sequence homology with AraC, we hypothesized that UreR contains both a dimerization domain and a DNA-binding domain. A translational fusion of the leucine zipper dimerization domain (amino acids 302 to 350) of C/EBP and the C-terminal half of UreR (amino acids 164 to 293) activated transcription from the ureD promoter (p(ureD)) and bound to a 60-bp fragment containing p(ureD), as analyzed by gel shift. These results were consistent with the DNA-binding specificity residing in the C-terminal half of UreR and dimerization being required for activity. To localize the dimerization domain of UreR, a translational fusion of the DNA-binding domain of the LexA repressor (amino acids 1 to 87) and the N-terminal half of UreR (amino acids 1 to 182) was constructed and found to repress transcription from p(sulA)-lacZ (sulA is repressed by LexA) and bind to the sulA operator site, as analyzed by gel shift. Since LexA binds this site only as a dimer, the UreR(1-182)-LexA(1-87) fusion also must dimerize to bind p(sulA). Indeed, purified UreR-Myc-
His
eluted from a gel filtration column as a dimer. Therefore, we conclude that the dimerization domain of UreR is located within the N-terminal half of UreR. UreR contains three leucines that mimic the leucines that contribute to dimerization of AraC. Mutagenesis of Leu147, Leu148, or L158 alone did not significantly affect UreR function. In contrast, mutagenesis of both Leu147 and Leu148 or all three Leu residues resulted in a 85 or 94% decrease, respectively, in UreR function in the presence of urea (P < 0.001). On the contrary, His102 and His175 mutations of UreR resulted in constitutive induction in the absence of urea. We conclude that a dimerization domain resides in the N-terminal half of the polypeptide, that Leu residues may contribute to this function, and that sequences within the C-terminal half of UreR are responsible for DNA binding to the
urease
promoter regions. Selected
His
residues also contribute significantly to UreR function.
...
PMID:Identification of the domains of UreR, an AraC-like transcriptional regulator of the urease gene cluster in Proteus mirabilis. 1144 87
UreE is proposed to be a metallochaperone that delivers nickel ions to
urease
during activation of this bacterial virulence factor. Wild-type Klebsiella aerogenes UreE binds approximately six nickel ions per homodimer, whereas H144*UreE (a functional C-terminal truncated variant) was previously reported to bind two. We determined the structure of H144*UreE by multi-wavelength anomalous diffraction and refined it to 1.5 A resolution. The present structure reveals an Hsp40-like peptide-binding domain, an Atx1-like metal-binding domain, and a flexible C terminus. Three metal-binding sites per dimer, defined by structural analysis of Cu-H144*UreE, are on the opposite face of the Atx1-like domain than observed in the copper metallochaperone. One metal bridges the two subunits via the pair of
His
-96 residues, whereas the other two sites involve metal coordination by
His
-110 and
His
-112 within each subunit. In contrast to the copper metallochaperone mechanism involving thiol ligand exchanges between structurally similar chaperones and target proteins, we propose that the Hsp40-like module interacts with
urease
apoprotein and/or other
urease
accessory proteins, while the Atx1-like domain delivers histidyl-bound nickel to the
urease
active site.
...
PMID:Crystal structure of Klebsiella aerogenes UreE, a nickel-binding metallochaperone for urease activation. 1159 23
Bacillus pasteurii UreE (BpUreE) is a putative chaperone assisting the insertion of Ni(2+) ions in the active site of
urease
. The x-ray structure of the protein has been determined for two crystal forms, at 1.7 and 1.85 A resolution, using SIRAS phases derived from a Hg(2+)-derivative. BpUreE is composed of distinct N- and C-terminal domains, connected by a short flexible linker. The structure reveals the topology of an elongated homodimer, formed by interaction of the two C-terminal domains through hydrophobic interactions. A single Zn(2+) ion bound to four conserved
His
-100 residues, one from each monomer, connects two dimers resulting in a tetrameric BpUreE known to be formed in concentrated solutions. The Zn(2+) ion can be replaced by Ni(2+) as shown by anomalous difference maps obtained on a crystal of BpUreE soaked in a solution containing NiCl(2). A large hydrophobic patch surrounding the metal ion site is surface-exposed in the biologically relevant dimer. The BpUreE structure represents the first for this class of proteins and suggests a possible role for UreE in the
urease
nickel-center assembly.
...
PMID:Structural basis for Ni(2+) transport and assembly of the urease active site by the metallochaperone UreE from Bacillus pasteurii. 1160 2
Helicobacter pylori is a human gastric pathogen that survives the strong acidity of the stomach by virtue of its
urease
activity. This activity produces ammonia, which neutralizes the bacterial microenvironment. UreI, an inner membrane protein, is essential for resistance to low pH and for the gastric colonization of mice by H. pylori. In the heterologous Xenopus oocytes expression system, UreI behaves like an H+-gated urea channel, and
His
-123 was found to be important for low pH activation. We investigated the role of UreI directly in H. pylori and showed that, in the presence of urea, strains expressing wild-type UreI displayed very rapid stimulation of extracellular ammonia production upon exposure to pH </= 5. This response was not observed when acetamide was used as a source of ammonia; therefore, it is specific for urea hydrolysis. To identify residues critical for UreI activity or activation, we constructed H. pylori strains carrying individual chromosomal mutations of UreI (i) in the four conserved
histidine
residues (H71, H123, H131, H193) and (ii) in a conserved region of the third intracellular loop (L165, G166, K167, F168). The distal H193 (and not H123) was found to be crucial for stimulating the production of ammonia at low pH; a single mutation in this residue uncoupled the UreI activity from its acid activation. The third intracellular loop of UreI was shown to be important for UreI activity. Thus, in H. pylori, UreI is necessary for the adaptation of
urease
activity to the extracellular pH. UreI behaves like a novel type of urea transporter, and the identification of residues essential for its function in H. pylori provides new insight into the unusual molecular mechanism of low pH activation.
...
PMID:The Helicobacter pylori UreI protein: role in adaptation to acidity and identification of residues essential for its activity and for acid activation. 1173 44
Nickel acquisition is necessary for
urease
activity, a major virulence factor of the human gastric pathogen Helicobacter pylori. The nickel permease NixA of H. pylori is a member of the single-component nickel-cobalt transporter family. To identify functionally relevant amino acids of NixA, single-site exchanges were introduced into NixA via PCR-based mutagenesis. This study investigated one of the recognition motifs for this family in transmembrane segment III and other conserved amino acids, mostly with possible nickel-binding capacities. The mutant alleles were expressed in Escherichia coli, and activity of the altered permeases was analyzed by measuring nickel accumulation and
urease
activity. Expression was checked by immunoblotting after sodium dodecyl sulfate-polyacrylamide gel electrophoresis with a NixA-specific antibody. Replacement of Phe-75 and
His
-79-both part of the characteristic sequence motif-and of Asn-127, Thr-195, and Ser-197 with alanine abolished nickel uptake in the E. coli system. The results were unchanged if these amino acids were replaced with residues more similar to the original amino acid. The phenotype of the null mutants was independent of the culture medium. Mutation of Val-82, Tyr-242, Thr-260,
His
-181, and
His
-15 strongly affected uptake activity under nickel limitation on complex Luria-Bertani medium but had little effect in minimal medium. Eight other conserved amino acids (Ser-80, Ser-81, Phe-119, Trp-180, Tyr-183, Trp-244, Pro-249, and Asn-256) were found to be dispensable for the function of NixA. These results show that atypical nickel-binding amino acids play an important function in nickel uptake and that most of the essential amino acids are clustered in conserved motifs.
...
PMID:Conserved low-affinity nickel-binding amino acids are essential for the function of the nickel permease NixA of Helicobacter pylori. 1184 75
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