Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:6.3.4.6 (urease)
 7,490 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In vivo urease metallocenter assembly in Klebsiella aerogenes requires the presence of several accessory proteins (UreD, UreF, and UreG) and is further facilitated by UreE. In this study, UreG was isolated and shown to be a monomer with an Mr of 21,814 +/- 20 based on gel filtration chromatography and mass spectrometric results. Although it contains a P-loop motif typically found in nucleotide-binding proteins, UreG did not bind or hydrolyze ATP or GTP, and it exhibited no affinity for ATP- and GTP-linked agarose resins. Site-directed mutagenesis of ureG allowed the substitution of Ala for Lys-20 or Thr-21 in the P-loop motif and resulted in the production of inactive urease in cells grown in the presence of nickel; hence, an intact P-loop may be essential for UreG to function in vivo. These mutant cells were unable to synthesize the UreD-UreF-UreG-urease apoprotein species that are thought to be the key urease activation complexes in the cell. An insoluble protein species containing UreD, UreF, and UreG (termed the DFG complex) was detected in cells carrying deletions in ureE and the urease structural genes. The DFG complex was solubilized in 0.5% Triton X-100 detergent, shown to bind to an ATP-linked agarose resin, and found to elute from the resin in the presence of Mg-ATP. In cells containing a UreG P-loop variant, the DFG complex was formed but did not bind to the nucleotide-linked resin. These results suggest that the UreG P-loop motif may be essential for nucleotide binding by the DFG complex and support the hypothesis that nucleotide hydrolysis is required for in vivo urease metallocenter assembly.
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PMID:Characterization of UreG, identification of a UreD-UreF-UreG complex, and evidence suggesting that a nucleotide-binding site in UreG is required for in vivo metallocenter assembly of Klebsiella aerogenes urease. 920 19

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.
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PMID:Characterisation of the urease gene cluster in Bordetella bronchiseptica. 952 76

Klebsiella aerogenes urease possesses a dinuclear metallocenter in which two nickel atoms are bridged by carbamylated Lys217. To assess whether carbamate-specific chemistry is required for urease activity, site-directed mutagenesis and chemical rescue strategies were combined in efforts to place a carboxylate group at the location of this metal ligand. Urease variants with Lys217 replaced by Glu, Cys, and Ala (K217E, K217C/C319A, and K217A proteins) were purified, shown to be activated by incubation with small organic acids plus Ni(II), and structurally characterized. K217C/C319A urease possessed a second change in which Cys319 was replaced by Ala in order to facilitate efforts to chemically modify Cys217; however, this covalent modification approach did not produce active urease. Chemical rescue of the K217E, K217C/C319A, and K217A variants required 2, 2, and 10 h, respectively, to reach maximal activity levels. The highest activity generated [224 micromol of urea degraded.min-1.(mg of protein)-1, for K217C/C319A urease incubated with 500 mM formic acid and 10 mM Ni at pH 6.5] corresponded to 56% of that measured for in vitro activation of the wild-type apoprotein. While the K217E apoprotein showed minimal structural perturbations, the K217C/C319A apoprotein showed a disordering of some active site residues, and the K217A apoprotein revealed a repositioning of His219 to allow the formation of a hydrogen bond with Thr169, thus replacing the hydrogen bond between the amino group of Lys217 and Thr169 in the native enzyme. Importantly, these structures allow rationalization of the relative rates and yields of chemical rescue experiments. The crystal structures of chemically rescued K217A and K217C/C319A ureases revealed a return of the active site residues to their wild-type positions. In both cases, noncovalently bound formate was structurally equivalent to the Lys-carbamate as the bridging metallocenter ligand. We conclude that carbamate-specific chemistry is not required for urease catalysis.
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PMID:Chemical rescue of Klebsiella aerogenes urease variants lacking the carbamylated-lysine nickel ligand. 955 61

A boy with a neuropathic bladder and a single hydronephrotic kidney developed hyperammonaemic encephalopathy during a urinary tract infection with Klebsiella oxytoca. Although particularly associated with Proteus infections and prune belly syndrome, hyperammonaemia can complicate infection with any urease-producing bacteria if there is urinary stasis.
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PMID:Hyperammonaemia due to Klebsiella infection in a neuropathic bladder. 981 90

A model of the catheterised bladder was used to test the ability of urease-producing urinary tract pathogens to encrust urethral catheters. Encrustation was assessed by determining the amounts of calcium and magnesium deposited on the catheters and visualised by scanning electron microscopy. Urease-positive Morganella morganii, Klebsiella pneumoniae, and Pseudomonas aeruginosa failed to raise the urinary pH and form crystalline biofilms. In contrast, strains of Proteus mirabilis, Proteus vulgaris, and Providencia rettgeri generated alkaline urine (pH 8.3-8.6) and extensive catheter encrustation within 24 h.
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PMID:Studies on the formation of crystalline bacterial biofilms on urethral catheters. 983 68

The urease accessory protein encoded by ureE from Klebsiella aerogenes is proposed to bind intracellular Ni(II) for transfer to urease apoprotein. While native UreE possesses a histidine-rich region at its carboxyl terminus that binds several equivalents of Ni, the Ni-binding sites associated with urease activation are internal to the protein as shown by studies involving truncated H144UreE [Brayman and Hausinger (1996) J. Bacteriol. 178, 5410-5416]. Nine potential Ni-binding residues (five His, two Cys, one Asp, and one Tyr) within H144UreE were independently substituted by mutagenesis to determine their roles in metal binding and urease activation. In vivo effects of these substitutions on urease activity were measured in Escherichia coli strains containing the K. aerogenes urease gene cluster with the mutated ureE genes. Several mutational changes led to reductions in specific activity, with substitution of His96 producing urease activity below the level obtained from a ureE deletion mutant. The metal-binding properties of purified variant UreE proteins were characterized by a combination of equilibrium dialysis and UV/visible, EPR, and hyperfine-shifted 1H NMR spectroscopic methods. Ni binding was unaffected for most H144UreE variants, but mutant proteins substituted at His110 or His112 exhibited greatly reduced affinity for Ni and bound one, rather than two, metal ions per dimer. Cys79 was identified as the Cu ligand responsible for the previously observed charge-transfer transition at 370 nm, and His112 also was shown to be associated with this chromophoric site. NMR spectroscopy provided clear evidence that His96 and His110 serve as ligands to Ni or Co. The results from these and other studies, in combination with prior spectroscopic findings for metal-substituted UreE [Colpas et al. (1998) J. Biol. Inorg. Chem. 3, 150-160], allow us to propose that the homodimeric protein possesses two nonidentical metal-binding sites, each symmetrically located at the dimer interface. The first equivalent of added Ni or Co binds via His96 and His112 residues from each subunit of the dimer, and two other N or O donors. Asp111 either functions as a ligand or may affect this site by secondary interactions. The second equivalent of Ni or Co binds via the symmetric pair of His110 residues as well as four other N or O donors. In contrast, the first equivalent of Cu binds via the His110 pair and two other N/O donors, while the second equivalent of Cu binds via the His112 pair and at least one Cys79 residue. UreE sequence comparisons among urease-containing microorganisms reveal that residues His96 and Asp111, associated with the first site of Ni binding, are highly conserved, while the other targeted residues are missing in many cases. Our data are most compatible with one Ni-binding site per dimer being critical for UreE's function as a metallochaperone.
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PMID:Identification of metal-binding residues in the Klebsiella aerogenes urease nickel metallochaperone, UreE. 1019 22

Expression of the active urease of the enterobacterium, Klebsiella aerogenes, requires the presence of the accessory genes (ureD, ureE, ureF, and ureG) in addition to the three structural genes (ureA, ureB, and ureC). These accessory genes are involved in functional assembly of the nickel-metallocenter for the enzyme. Characterization of ureF gene has been hindered, however, since the UreF protein is produced in only minute amount compared to other urease gene products. In order to overexpress the ureF gene, a recombinant pMAL-UreF plasmid was constructed from which the UreF was produced as a fusion with maltose-binding protein. The MBP-UreF fusion protein was purified by using an amylose-affinity column chromatography followed by an anion exchange column chromatography. Polyclonal antibodies raised against the fusion protein were purified and shown to specifically recognize both MBP and UreF peptides. The UreF protein was shown to be unstable when separated from MBP by digestion with factor Xa.
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PMID:Expression of the recombinant Klebsiella aerogenes UreF protein as a MalE fusion. 1040 30

Syntheses of metal-containing enzymes often require the participation of accessory proteins. The roles played by many of these accessory proteins are poorly characterized. Klebsiella aerogenes urease, a nickel-containing enzyme, provides an ideal system to study metallocenter assembly. Here, we describe a method for isolating a complex containing urease apoprotein and the UreD, UreF, and UreG accessory proteins. We demonstrate that urease apoprotein in this complex is activated to near wild-type enzyme levels when incubated with nickel ions and high (approximately 100 mM) concentrations of bicarbonate. Significantly, we also observed nickel-dependent activation at physiologically relevant (approximately 100 microM) bicarbonate levels, but only in the presence of GTP. Based on studies involving a nonhydrolyzable analog of GTP, we conclude that nucleotide hydrolysis, not just binding, is required for this process. The critical nucleotide-binding site was localized to UreG on the basis of experiments using a variant complex. These studies highlight the relevance of the UreD-UreF-UreG-urease apoprotein complex to nickel metallocenter assembly and explain the previously identified in vivo energy requirement for urease activation.
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PMID:GTP-dependent activation of urease apoprotein in complex with the UreD, UreF, and UreG accessory proteins. 1050 Jan 43

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.
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PMID:In vivo and in vitro kinetics of metal transfer by the Klebsiella aerogenes urease nickel metallochaperone, UreE. 1075 63

Klebsiella aerogenes urease uses a dinuclear nickel active site to catalyze the hydrolysis of urea. Here, we describe the steady-state and pre-steady-state kinetics of urease inhibition by fluoride. Urease is slowly inhibited by fluoride in both the presence and absence of substrate. Steady-state rate studies yield parallel double-reciprocal plots; however, we show that fluoride interaction with urease is not compatible with classical uncompetitive inhibition. Rather, we propose that fluoride binds to an enzyme state (E) that is in equilibrium with resting enzyme (E) and produced during catalysis. Fluoride binding rates are directly proportional to inhibitor concentration. Substrate reduces both the rate of fluoride binding to urease and the rate of fluoride dissociation from the complex, consistent with urea binding to E and E.F in addition to E. Fluoride inhibition is pH-dependent due to a protonation event linked to fluoride dissociation. Fluoride binding is pH-independent, suggesting that fluoride anion, not HF, is the actual inhibitor. We assess the kinetic results in terms of the known protein crystal structure and evaluate possible molecular interpretations for the structure of the E state, the site of fluoride binding, and the factors associated with fluoride release. Finally, we note that the apparent uncompetitive inhibition by fluoride as reported for several other metalloenzymes may need to be reinterpreted in terms of fluoride interaction with the corresponding E states.
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PMID:Fluoride inhibition of Klebsiella aerogenes urease: mechanistic implications of a pseudo-uncompetitive, slow-binding inhibitor. 1082 10


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