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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
Mol Microbiol 2001 Nov
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

Acidification of vesicular compartments plays an important role in a number of cellular transport processes, including protein secretion, metal cofactor insertion, glycosylation and pH stability. In the present study, we identify and characterize a component of the vesicular proton pump, Vph1p, to determine its role in the virulence of the AIDS-related fungal pathogen Cryptococcus neoformans. Insertional mutagenesis and plasmid rescue were used to identify the VPH1 gene by screening for mutants defective in laccase activity. Disruption of VPH1 resulted in defects in three virulence factors (capsule production, laccase and urease expression), as well as a growth defect at 37 degrees C, but only a small growth reduction at 30 degrees C. These effects were duplicated by the vacuolar (H+)-ATPase inhibitor bafilomycin A1. Furthermore, the vph1 insertional mutant was also avirulent in a mouse meningo-encephalitis model. Complementation of the insertional mutant with wild-type VPH1 resulted in a recovery of virulence factor expression, normal growth at 37 degrees C and restoration of full virulence. These studies establish the importance of the VPH1 gene and vesicular acidification in the virulence of C. neoformans.
Mol Microbiol 2001 Nov
PMID:Multiple virulence factors of Cryptococcus neoformans are dependent on VPH1. 1173 51

Intron-encoded U17 RNA is a member of the H/ACA box class of small nucleolar RNAs (snoRNAs) involved in ribosomal RNA (rRNA) maturation. U17 snoRNA shows typical characteristics of guide RNAs, which specify sites of pseudouridylation on the precursor rRNA (pre-rRNA). However, in spite of the presence of H and ACA boxes and short regions complementary to the pre-rRNA, its secondary structure does not show any evident pseudouridylation pocket. Moreover, its length is larger than the typical one of snoRNAs and it shows a more complex secondary structure compared to the canonical hairpin-hinge-hairpin-tail architecture. Greater knowledge of eukaryotic U17 snoRNA structure is needed to understand its precise function. Comparative molecular studies of this snoRNA with different vertebrates is still limited to a few cases. With the aim of increasing our understanding of the U17 snoRNA secondary structure, we cloned the U17 snoRNA coding sequence from 10 additional vertebrate taxa. On the basis of structure homology derived from sequence comparison and thermodynamic prediction, we propose a vertebrate consensus secondary structure and novel conserved sequence boxes for U17 snoRNA. Host gene localization of U17 coding sequence and its ability to serve as a guide sequence for RNA/RNA interaction has been evolutionarily traced from fish to mammals. It is interesting to note that turtle U17 snoRNAs show a noncanonical ACA box, mainly consisting in the GCA box. Microinjections in X. laevis oocytes of in vitro synthesized turtle transcripts containing the U17 RNA sequence which have canonical ACA, wild-type GCA, and mutated CCA and UCA boxes resulted in efficient production of mature U17 snoRNA.
J Mol Evol 2002 Feb
PMID:Comparative structure analysis of vertebrate U17 small nucleolar RNA (snoRNA). 1182 10

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.
Mol Microbiol 2002 Feb
PMID:An ABC-type, high-affinity urea permease identified in cyanobacteria. 1192 26

Human renal dipeptidase is a membrane-bound glycoprotein hydrolyzing dipeptides and is involved in hydrolytic metabolism of penem and carbapenem beta-lactam antibiotics. The crystal structures of the saccharide-trimmed enzyme are determined as unliganded and inhibitor-liganded forms. They are informative for designing new antibiotics that are not hydrolyzed by this enzyme. The active site in each of the (alpha/beta)(8) barrel subunits of the homodimeric molecule is composed of binuclear zinc ions bridged by the Glu125 side-chain located at the bottom of the barrel, and it faces toward the microvillar membrane of a kidney tubule. A dipeptidyl moiety of the therapeutically used cilastatin inhibitor is fully accommodated in the active-site pocket, which is small enough for precise recognition of dipeptide substrates. The barrel and active-site architectures utilizing catalytic metal ions exhibit unexpected similarities to those of the murine adenosine deaminase and the catalytic domain of the bacterial urease.
J Mol Biol 2002 Aug 09
PMID:Crystal structure of human renal dipeptidase involved in beta-lactam hydrolysis. 1214 77

Urea uptake in eukaryotes and prokaryotes occurs via diffusion or active transport across the cell membrane. Facilitated diffusion of urea in both types of organisms requires a single-component channel. In bacteria, these transport systems allow rapid access of urease to its substrate, resulting in ammonia production, which is needed either for resistance to acidity or as a nitrogen source. In Yersinia pseudotuberculosis, a ureolytic enteropathogenic bacterium, a gene of unknown function (yut) located near the urease locus was found to encode a putative membrane protein with weak homology to single-component eukaryotic urea transporters. When expressed in Xenopus oocytes, Yut greatly increases cellular permeability to urea. Inactivation of yut in Y. pseudotuberculosis results in diminished apparent urease activity and reduced resistance to acidity in vitro when urea is present in the medium. In the mouse model, bacterial colonization of the intestine mucosa is delayed with the Yut-deficient mutant. Although structurally unrelated, Yut and the Helicobacter pylori UreI urea channel were shown to be functionally interchangeable in vitro and are sufficient to allow urea uptake in both bacteria, thereby confirming their function in the respective parent organisms. Homologues of Yut were found in other yersiniae, Actinobacillus pleuropneumoniae, Brucella melitensis, Pseudomonas aeruginosa and Staphylococcus aureus. The Y. pseudotuberculosis Yut protein is therefore the first member of a novel class of bacterial urea permeases related to eukaryotic transporters.
Mol Microbiol 2002 Aug
PMID:The Yersinia pseudotuberculosis Yut protein, a new type of urea transporter homologous to eukaryotic channels and functionally interchangeable in vitro with the Helicobacter pylori UreI protein. 1218 Sep 33

Urease from seeds of pigeonpea showed a time-dependent and irreversible inactivation at very low concentrations of heavy metal ions. Concentration of Cu(2+), Hg(2+) and Ag(+) required for 50% inactivation, on 10 min of incubation, were found to be 2.2 x 10(-6), 2.9 x 10(-8) and 6.3 x 10(-12) M, respectively. The kinetics of inactivation with each of these metal ions was found to be biphasic, with half of the activity being lost in a fast phase and remaining in a slow phase. Acetohydroxamate (AHA) inhibits pigeonpea urease competitively and reversibly with a K(i) of 0.041 mM at pH 7.3. This inhibition was found to be pH dependent. A reversible and time-dependent inhibition was observed with AHA. AHA inhibition revealed biphasic kinetics as observed with the heavy metal ions. Pigeonpea urease was also inhibited by fluoride ions competitively with a K(i) value of 1.23 mM. These inhibition studies suggest the possible interaction of these inhibitors with active site thiol groups and Ni (II) ion. A mechanism has been proposed for each of these inhibitors and compared with inhibition studies reported for other ureases.
J Biochem Mol Biol Biophys 2002 Feb
PMID:Kinetics of inhibition and molecular asymmetry in pigeonpea (Cajanus cajan) urease. 1218 75

Plant orthologs of the bacterial urease accessory genes ureD and ureF, which are required for the insertion of the nickel ion at the active site, have been isolated from soybean ( Glycine max L. Merr.), tomato ( Lycopersicon esculentum) and Arabidopsis thaliana. The functionality of soybean UreD and UreF was tested by measuring their ability to complement urease-negative mutants of Schizosaccharomyces pombe, a eukaryote which produces a "plant-like" urease of ~90 kDa. The S. pombe ure4 mutant was complemented by a 12-kb fragment of S. pombe genomic DNA, which was shown by PCR to contain a putative ureD gene. However, ure4 was not complemented by a UreD cDNA soybean, expressed under the control of a strong promoter. In contrast, an S. pombe ure3 mutation was complemented by both a 10-kb fragment of S. pombe DNA containing ureF and the UreF cDNA from soybean. Soybean Eu2 is a candidate urease accessory gene; its product cooperates with the Eu3 protein in activating apourease in vitro. However, the sequences of UreD and UreF transcripts from two eu2/eu2 mutants, recovered as RT-PCR products, revealed no mutational alteration, suggesting that Eu2 encodes neither UreD nor UreF.
Mol Genet Genomics 2002 Dec
PMID:Activation of the urease of Schizosaccharomyces pombe by the UreF accessory protein from soybean. 1247 50

The pathogenic yeast Cryptococcus neoformans (Cn) var. gattii causes meningoencephalitis in healthy individuals, unlike the better known Cn varieties grubii and neoformans, which are common in immunocompromised individuals. The virulence determinants and mechanisms of host predilection are poorly defined for var. gattii. The present study focused on the characterization of a Cu,Zn superoxide dismutase (SOD1) gene knock-out mutant constructed by developing a DNA transformation system. The sod1 mutant was highly sensitive to the redox cycling agent menadione, and showed fragmentation of the large vacuole in the cytoplasm, but no other defects were seen in growth, capsule synthesis, mating, sporulation, stationary phase survival or auxotrophies for sulphur-containing amino acids. The sod1 mutant was markedly attenuated in virulence in a mouse model, and it was significantly susceptible to in vitro killing by human neutrophils (PMNs). The deletion of SOD1 also resulted in defects in the expression of a number of virulence factors, i.e. laccase, urease and phospholipase. Complementation of the sod1 mutant with SOD1 resulted in recovery of virulence factor expression and menadione resistance, and in restoration of virulence. Overall, these results suggest that the antioxidant function of Cu,Zn SOD is critical for the pathogenesis of the fungus, but is dispensable in its saprobic life. This report constitutes the first instance in which superoxide dismutase has been directly implicated in the virulence of a fungal pathogen.
Mol Microbiol 2003 Mar
PMID:Characterization of Cu,Zn superoxide dismutase (SOD1) gene knock-out mutant of Cryptococcus neoformans var. gattii: role in biology and virulence. 1262 21

Comparative physiological studies are a powerful tool for revealing common animal adaptations. Amino acid catabolism produces ammonia which is detoxified through the synthesis of urea (mammals, some fish), uric acid (birds), or urea and uric acid (reptiles). In mammalian herbivores and omnivores, urea nitrogen is salvaged by a series of steps involving urea transfer into the intestine, microbial mediated urea hydrolysis with synthesis of amino acids utilizing the liberated ammonia and transfer of the amino acids back to the host. A similar series of steps occur in omnivorous/granivorous and herbivorous birds, although in this case urine, containing uric acid, is refluxed directly into the intestine where microbes degrade the uric acid and utilize the liberated ammonia for amino acid synthesis. These amino acids are transferred back to the host. In reptiles and ureotelic fish not all of these steps have been experimentally confirmed. Reptiles like birds, reflux urine into the intestine where it is exposed to the microflora. However, the capacity of these microbes to breakdown the uric acid and urea and utilize ammonia for amino acid synthesis has not been documented. Ureotelic fish transfer urea into the intestine where urease (presumably of bacterial origin) hydrolyzes the urea. However, the amino acid synthesizing capacity of the intestinal microflora has not been studied. The series of steps, as outlined, would define the prevailing nitrogen conservation system for herbivores and omnivores at least. However, it would appear that some animals, in particular the fruit-eating bat and perhaps the fruit-eating bird, may have evolved alternative, as yet uncharacterized, adaptations to a very limited nitrogen intake.
Comp Biochem Physiol B Biochem Mol Biol 2003 Apr
PMID:Do mammals, birds, reptiles and fish have similar nitrogen conserving systems? 1267 Jul 82


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