Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

The DNA sequence has been determined upstream of the amiE structural gene in the amidase operon of Rhodococcus sp. R312 and a new ORF (amiS2) identified. The amiS2 gene encodes a potential 206 amino acid (aa) protein containing a high proportion of hydrophobic residues. The AmiS2 protein possesses high homology to the ORFP3, amiS and ureI gene products from the Mycobacterium smegmatis (Ms) acetamidase operon, Pseudomonas aeruginosa (Pa) amidase operon and Helicobacter pylori (Hp) urease operon, respectively. Hydropathic analysis and secondary structure prediction of AmiS2 suggested the presence of seven potential transmembrane (TM) alpha-helices. Sequence analysis of the amiB2 gene, located downstream of the Rhodococcus sp. R312 amiE gene, showed that it encoded a 351-aa protein containing a potential ATP-binding motif. AmiB2 showed significant homology with the ATP-binding subunit of the bacterial Clp protease and high homology with the amiB product located within the Pa amidase operon. AmiB2 and AmiS2 appear to be two components of a recently identified novel family of ABC transporters (Wilson et al., 1995) and might be responsible for the adsorption of amidase substrates or release of their hydrolysis products.
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PMID:Amide metabolism: a putative ABC transporter in Rhodococcus sp. R312. 898 91

Helicobacter pylori urease requires nickel ions in the enzyme active site for catalytic activity. Nickel ions must, therefore, be actively acquired by the bacterium. NixA (high-affinity nickel transport protein)-deficient mutants of H. pylori retain significant urease activity, suggesting the presence of alternate nickel transporters. Analysis of the nucleotide sequence of the H. pylori genome revealed a homolog of NikD, a component of an ATP-dependent nickel transport system in Escherichia coli. Based on this sequence, a 378-bp DNA fragment was PCR amplified from H. pylori genomic DNA and used as a probe to identify an H. pylori lambda ZAPII genomic library clone that carried these sequences. Four open reading frames of 621, 273, 984, and 642 bp (abcABCD) were revealed by sequencing and predicted polypeptides of 22.7, 9.9, 36.6, and 22.8 kDa, respectively. The 36.6-kDa polypeptide (AbcC) has significant homology (56% amino acid sequence identity) to an E. coli ATP-binding protein component of an ABC transport system, while none of the other putative proteins are significantly homologous to polypeptides in the available databases. To determine the possible contribution of these genes to urease activity, abcC and abcD were each insertionally inactivated with a kanamycin resistance (aphA) cassette and allelic exchange mutants of each gene were constructed in H. pylori UMAB41. Mutation of abcD resulted in an 88% decrease in urease activity to 27 +/- 31 mumol of NH3/min/mg of protein (P < 0.0001), and a double mutant of nixA and abcC resulted in the near abolishment of urease activity (1.1 +/- 1.4 mumol of NH3/min/mg of protein in the double mutant versus 228 +/- 92 mumol of NH3/min/mg of protein in the parent [P < 0.0001]). Synthesis of urease apoenzyme, however, was unaffected by mutations in any of the abc genes. We conclude that the abc gene cluster, in addition to nixA, is involved in production of a catalytically active urease.
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PMID:Helicobacter pylori ABC transporter: effect of allelic exchange mutagenesis on urease activity. 929 50

Urea is an important nitrogen source for many microorganisms, but urea active transporters have not been characterized at a molecular level in any bacterium. Cells of Synechocystis sp. PCC 6803 and Anabaena sp. PCC 7120 exhibited the capacity to take up [14C]-urea from low-concentration (<1 microM) urea solutions. The Ks of Anabaena cells for urea was about 0.11 microM, and the observed uptake activity involved the transport and metabolism of urea. In contrast to urease, which was constitutively ex-pressed, expression of the high-affinity urea uptake activity was subjected to nitrogen control. In an Anabaena ureG (urease-) mutant, a concentrative, active transport of urea could be demonstrated. We found that a mutant of open reading frame (ORF) sll0374 from the Synechocystis genomic sequence lacked urea transport activity. This ORF encoded a conserved component of an ABC-type transporter, but it is not clustered together with any other possible transporter-encoding gene. An Anabaena homologue of sll0374, urtE, was isolated and found to be part of a cluster of genes, urtABCDE, putatively encoding all the elements of an ABC-type permease. Although the longest transcript that we could detect only covered urtABC, the impairment of urea transport by inactivation of urtA, urtB or urtE suggested that the whole gene cluster is expressed producing the urea permease. Expression was induced under nitrogen-limiting conditions, and a complex promoter regulated by the cyanobacterial global nitrogen control transcription factor NtcA was found upstream from urtA. Our work adds urea to the known substrates of the versatile class of ABC-type transporters and suggests the involvement of a transporter of this superfamily in urea scavenging by some bacteria in natural environments.
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PMID:An ABC-type, high-affinity urea permease identified in cyanobacteria. 1192 26

The molecular identification of the Corynebacterium glutamicum urea uptake system is described. This ABC-type transporter is encoded by the urtABCDE operon, which is transcribed in response to nitrogen limitation. Expression of the urt genes is regulated by the global nitrogen regulator AmtR, and an amtR deletion strain showed constitutive expression of the urtABCDE genes. The AmtR repressor protein also controls transcription of the urease-encoding ureABCEFGD genes in C. glutamicum. The ure gene cluster forms an operon which is mainly transcribed in response to nitrogen starvation. To confirm the increased synthesis of urease subunits under nitrogen limitation, proteome analyses of cytoplasmic protein extracts from cells grown under nitrogen surplus and nitrogen limitation were carried out, and five of the seven urease subunits were identified.
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PMID:Molecular identification of the urea uptake system and transcriptional analysis of urea transporter- and urease-encoding genes in Corynebacterium glutamicum. 1551 78

Nitrogen sources commonly used by cyanobacteria include ammonium, nitrate, nitrite, urea and atmospheric N(2), and some cyanobacteria can also assimilate arginine or glutamine. ABC (ATP-binding cassette)-type permeases are involved in the uptake of nitrate/nitrite, urea and most amino acids, whereas secondary transporters take up ammonium and, in some strains, nitrate/nitrite. In cyanobacteria, nitrate and nitrite reductases are ferredoxin-dependent enzymes, arginine is catabolized by a combination of the urea cycle and arginase pathway, and urea is degraded by a Ni(2+)-dependent urease. These pathways provide ammonium that is incorporated into carbon skeletons through the glutamine synthetase-glutamate synthase cycle, in which 2-oxoglutarate is the final nitrogen acceptor. The expression of many nitrogen assimilation genes is subjected to regulation being activated by the nitrogen-control transcription factor NtcA, which is autoregulatory and whose activity appears to be influenced by 2-oxoglutarate and the signal transduction protein P(II). In some filamentous cyanobacteria, N(2) fixation takes place in specialized cells called heterocysts that differentiate from vegetative cells in a process strictly controlled by NtcA.
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PMID:Nitrogen assimilation and nitrogen control in cyanobacteria. 1566 95

Urea transporters in bacteria are relatively rare. There are three classes, the ABC transporters such as those expressed by cyanobacteria and Corynebacterium glutamicum, the Yut protein expressed by Yersinia spp and the UreI expressed by gastric Helicobacter spp. This review focuses largely on the UreI proton-gated channel that is part of the acid acclimation mechanism essential for gastric colonization by the latter. UreI is a six-transmembrane polytopic integral membrane protein, N and C termini periplasmic, and is expressed in all gastric Helicobacter spp that have been studied but also in Helicobacter hepaticus and Streptococcus salivarius. The first two are proton-gated, the latter is pH insensitive. Site-directed mutagenesis and chimeric constructs have identified histidines and dicarboxylic amino acids in the second periplasmic loop of H. pylori and the first loop of H. hepaticus UreI and the C terminus of both as involved in a hydrogen-bonding dependence of proton gating, with the membrane domain in these but not in the UreI of S. salivarius responding to the periplasmic conformational changes. UreI and urease are essential for gastric colonization and urease associates with UreI during acid exposure, facilitating activation of the UreA and UreB apoenzyme complex by Ni2+ insertion by the UreF-UreH and UreE-UreG assembly proteins. Transcriptome analysis of acid responses of H. pylori also identified a cytoplasmic and periplasmic carbonic anhydrase as responding specifically to changes in periplasmic pH and these have been shown to be essential also for acid acclimation. The finding also of upregulation of the two-component histidine kinase HP0165 and its response element HP0166, illustrates the complexity of the acid acclimation processes involved in gastric colonization by this pathogen.
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PMID:Urea transport in bacteria: acid acclimation by gastric Helicobacter spp. 1726 89

The oligopeptide transport systems Opp belong to the nickel/peptide/opine PepT subfamily of ABC-transporters. The opportunist pathogen Staphylococcus aureus encodes four putative Opps and one orphean substrate binding protein Opp5A. Here, we report that the Opp2 permease complex (Opp2BCDF) and Opp5A are involved in nickel uptake and then renamed them NikBCDE and NikA respectively. S. aureus carries also a high-affinity nickel transporter NixA belonging to the NiCoT family of secondary transporters. The activity of these two nickel transporters determine that of urease, a multimeric nickel-dependent enzyme mainly involved in the neutralization of acidic environments. However, only the Nik system was responsible for the neutralization and deposit of pH-dependent crystals in human urine. Inactivation of the nik genes affected bacterial colonization of mouse urinary tract, as well as the 50% infective dose levels compared with the parental and nixA strains. Finally, complementation of the nik mutations restored bacterial colonization. Together, our results suggest a role for the Nik system in the urinary tract infection by S. aureus, probably due to the urease-mediated pH increase of the urine.
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PMID:A nickel ABC-transporter of Staphylococcus aureus is involved in urinary tract infection. 2066 75

Energy-coupling factor (ECF) transporters form a distinct group of ABC-type micronutrient importers in prokaryotes that do not contain extracytoplasmic, soluble substrate-binding proteins. Instead, they consist of a transmembrane substrate-specific S component that interacts with a module composed of a moderately conserved transmembrane (T) component and ABC ATPases. The majority of S components is considered to act as high-affinity binding proteins that strictly depend on their cognate T and ATPase units for transport activity. For a fraction of biotin-specific S units, however, transport activity was demonstrated in their solitary state. Here, we compared the activities of nickel- and cobalt-specific ECF transporters in the presence and absence of their T and ATPase units. Accumulation assays with radioactive metal ions showed that the truncated transporters led to approx. 25% of cell-bound radioactivity compared to the holotransporters. Activity of urease, an intracellular nickel-dependent enzyme, was used as a reporter and clearly indicated that the cell-bound radioactivity correlates with the cytoplasmic metal concentration. The results demonstrate that S units of metal transporters not only bind their substrates on the cell surface but mediate transport across the membrane, a finding of general importance on the way to understand the mechanism of ECF transporters.
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PMID:Transport of nickel and cobalt ions into bacterial cells by S components of ECF transporters. 2478 25

In human pathogenic bacteria, nickel is required for the activation of two enzymes, urease and [NiFe]-hydrogenase, necessary for host infection. Acquisition of Ni(II) is mediated by either permeases or ABC-importers, the latter including a subclass that involves an extracytoplasmic nickel-binding protein, Ni-BP. This study reports on the structure of three Ni-BPs from a diversity of human pathogens and on the existence of three new nickel-binding motifs. These are different from that previously described for Escherichia coli Ni-BP NikA, known to bind nickel via a nickelophore, and indicate a variegated ligand selectivity for Ni-BPs. The structures are consistent with ligand affinities measured in solution by calorimetry and challenge the hypothesis of a general requirement of nickelophores for nickel uptake by canonical ABC importers. Phylogenetic analyses showed that Ni-BPs have different evolutionary origins and emerged independently from peptide-binding proteins, possibly explaining the promiscuous behavior of this class of Ni(II) carriers.
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PMID:Promiscuous nickel import in human pathogens: structure, thermodynamics, and evolution of extracytoplasmic nickel-binding proteins. 2519 91

Nickel enzymes allow microorganisms to access chemistry that can be vital for survival and virulence. In this review we highlight recent work on several systems that import nickel ions and deliver them to the active sites of these enzymes. Small molecules, in particular l-His and derivatives, may chelate nickel ions before import at TonB-dependent outer-membrane and ABC-type inner-membrane transporters. Inside the cell, nickel ions are used by maturation factors required to produce nickel enzymes such as [NiFe]-hydrogenase, urease and lactate racemase. These accessory proteins often exhibit metal selectivity and frequently include an NTP-hydrolyzing metallochaperone protein. The research described provides a deeper understanding of the processes that allow microorganisms to access nickel ions from the environment and incorporate them into nickel proteins.
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PMID:Microbial nickel: cellular uptake and delivery to enzyme centers. 2821 82


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