EC:6.3.4.6 - FACTA Search

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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)

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

Hydantoinases are valuable enzymes for the production of optically pure D- and L-amino acids. They catalyse the reversible hydrolytic ring cleavage of hydantoin or 5'-monosubstituted hydantoins and are therefore classified in the EC nomenclature as cyclic amidases (EC 3.5.2.). In the EC nomenclature, four different hydantoin-cleaving enzymes are described: dihydropyrimidinase (3.5.2.2), allantoinase (EC 3.5.2.5), carboxymethylhydantoinase (EC 3.5.2.4), and N-methylhydantoinase (EC 3.5.2.14). Beside these, other hydantoinases with known metabolic functions, such as imidase and carboxyethylhydantoinase and enzymes with unknown metabolic function, are described in the literature and have not yet been classified. An important question is whether the distinct hydantoinases, which are frequently classified as L-, D-, and non-selective hydantoinases depending on their substrate specificity and stereoselectivity, are related to each other. In order to investigate the evolutionary relationship, amino acid sequence data can be used for a phylogenetic analysis. Although most of these enzymes only share limited sequence homology (identity < 15%) and therefore are only distantly related, it can be shown (i) that most of them are members of a broad set of amidases with similarities to ureases and build a protein superfamily, whereas ATP-dependent hydantoinases are not related, (ii) that the urease-related amidases have evolved divergently from a common ancestor and (iii) that they share a metal-binding motif consisting of conserved histidine residues. The difference in enantioselectivity used for the classification of hydantoinases on the basis of their biotechnological value does not reflect their evolutionary relationship, which is to a more diverse group of enzymes than was assumed earlier. This protein superfamily probably has its origin in the prebiotic conditions of the primitive earth.
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PMID:Microbial hydantoinases--industrial enzymes from the origin of life? 1022 78

UV-exposure of the epidermis leads to the isomerisation of trans-UCA into cis-UCA as well as to the generation of hydroxyl radicals. This study shows by means of the deoxyribose degradation test that UCA isomers are more powerful hydroxyl radical scavengers than the other 4-(5-)substituted imidazole derivatives, such as histidine, though less powerful than uric acid. UCA, present in relatively high concentrations in the epidermis, may well be a major natural hydroxyl radical scavenger.
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PMID:Urocanic acid isomers are good hydroxyl radical scavengers: a comparative study with structural analogues and with uric acid. 1036 66

Helicobacter spp., except for Helicobacter cinaedi, have only rarely been reported in cases of septicemia. A patient with X-linked (Bruton's) agammaglobulinemia was found to have persistent sepsis with a Helicobacter-like organism despite multiple courses of antibiotics. His periods of sepsis were associated with leg swelling thought to be consistent with cellulitis. The organism was fastidious and required a microaerophilic environment containing H(2) for growth. Optimal growth was observed at 35 to 37 degrees C on sheep blood, CDC anaerobe, and Bordet-Gengou agars. Serial subcultures every 4 to 5 days were required to maintain viability. The organism was strongly urease positive and showed highest relatedness to Helicobacter-like organisms with the vernacular name "Flexispira rappini" by 16S rRNA gene sequence analysis. Genomic DNA hybridization studies, however, found 24 to 37% relatedness to "F. rappini" and even less to other Helicobacter spp. Although the organism phenotypically resembles "Flexispira" and Helicobacter, it is thought to represent a new taxon. The patient's infection was eventually cleared with a prolonged (5-month) course of intravenous imipenem and gentamicin.
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PMID:Recurrent bacteremia caused by a "Flexispira"-like organism in a patient with X-linked (Bruton's) agammaglobulinemia. 1040 81

UV-B radiation suppresses cell-mediated immunity. Histidine forms trans-urocanic acid (trans-UCA) enzymatically in the stratum corneum. Photoisomerization of trans-UCA to cis-urocanic acid (cis-UCA) has been proposed for the initiation of an immunosuppressive process. Many microorganisms described in the literature metabolize histidine and/or trans-UCA. Our enrichment cultures of soil and sewage contain organisms that can degrade cis-UCA. We have tested microorganisms for degradation of cis-UCA, trans-UCA, or L-histidine when they are incorporated at 0.2% in nutrient broth. Six out of 10 selected genera isolated by our clinical microbiology laboratory degrade one or more of the imidazole substrates. We have cultured over 60 aerobic isolates from human skin. Of these, 33 degrade one or more of the three imidazole substrates and 12 degrade cis-UCA. Isolates from BALB/c mice are also active on cis-UCA. We have identified a cis-UCA-degrading bacterium as Micrococcus luteus. Four ATCC strains of M. luteus have been tested and three are active on histidine or trans-UCA; two are active on cis-UCA. Micrococci that degrade cis-UCA contain a new enzyme, cis-UCA isomerase, which converts the substrate to the trans-isomer. This enzyme provides access to the classical L-histidine degradation pathway. We hypothesize that an epidermal microflora that degrades L-histidine, trans-UCA, or cis-UCA influences the concentration of urocanic acids on the skin and, thus, affects immune suppression.
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PMID:The degradation of L-histidine and trans- and cis-urocanic acid by bacteria from skin and the role of bacterial cis-urocanic acid isomerase. 1044 33

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.
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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.
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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.
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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.
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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.
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PMID:Sites of pH regulation of the urea channel of Helicobacter pylori. 1144 25

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