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Arginine is rapidly depleted from the medium during the cultivation of T. vaginalis in a defined or semi-defined medium. It is broken down to ornithine, ammonia and carbon dioxide by the three enzymes of the dihydrolase pathway: arginine deiminase, catabolic ornithine carbamyltransferase (OCTase) and carbamate kinase. Arginase and urease as well as citrulline hydrolase appear to be absent. Ornithine, a product of the pathway was further converted to putrescine by an active ornithine decarboxylase. Apparent substrate Km values determined were arginine deiminase, 103 microM; catabolic OCTase, 71 microM; ornithine decarboxylase 134 microM. A substrate level phosphorylation is associated with the pathway; the significance of this to the overall energy economy of the cell is unclear.
Mol Biochem Parasitol 1983 Jul
PMID:The pathway of arginine catabolism in the parasitic flagellate Trichomonas vaginalis. 631 11

We have cloned and sequenced the wild-type and suppressor alleles of the S. pombe sup8 tRNA gene. The wild-type allele has a leucine UAA anticodon and the suppressor (sup8-e) carries the opal suppressor anticodon UCA. The gene has a 16 base pair intervening sequence that, in the RNA, is predicted to form a secondary structure which involves base pairing to the 5', rather than the usual 3' side of the 5' splice site. When incubated in Saccharomyces cerevisiae cell-free extracts both alleles are efficiently transcribed, the 5' leader and 3' trailer sequences are removed and CCA is added to the 3' processed end; however, the intervening sequence is not excised. This finding implies that the structural requirements of the splicing endonucleases in the two yeasts have diverged. No other tRNA genes with related sequences were detected in S. pombe DNA by hybridization, suggesting that other UUA isoacceptors may be structurally dissimilar to sup8 or that the UUA codon may be decoded by a UUG leucine isoacceptor.
Mol Gen Genet 1984
PMID:The sup8 tRNALeu gene of Schizosaccharomyces pombe has an unusual intervening sequence and reduced pairing in the anticodon stem. 659 38

The sequence and presumptive structure of a tRNA trp gene from Paramecium tetraaurelia are given. The gene is located 1,500 bp downstream from the 13S rRNA gene, in about the middle of the genome. Paramecium tRNA trp has a completely normal TpsiC loop and stem, however its anticodon (UCA) constitutes an alteration in the "universal" genetic code, similar to those seen in fungal and mammalian mitochondria. Most features of Paramecium tRNA trp resemble other mitochondrial counterparts; however, its sequence is more homologous to the "unaltered" tRNA trp (anticodon CCA) from E. coli. Paramecium mitochondria may resemble a primitive stage of organelle evolution.
Mol Gen Genet 1982
PMID:Altered genetic code in Paramecium mitochondria: possible evolutionary trends. 696 Feb 26

Urease activity is produced by members of the family Enterobacteriaceae that contain the plasmid-encoded urease locus only when urea is present in the growth medium. The plasmid-encoded urease locus contains seven tandem urease structural and accessory genes (ureDABCEFG). Previously we showed that transcription of the first gene in this cluster, ureD, is initiated at a urea-dependent promoter (ureDp). Expression from ureDp requires the product of ureR, which is transcribed divergently from the plasmid-encoded ureDABCEFG. From DNA sequence analysis, UreR is predicted to be a 34 kDa protein with identity to the AraC family of transcriptional activators. In this report we demonstrate that there are two additional urea and UreR-dependent promoters within the plasmid-encoded urease locus: ureRp and ureGp. A low-level constitutive promoter was also identified upstream of ureE (ureEp). Three major mRNA transcripts were induced when urea was present in the growth medium: a transcript containing ureDABCEF, a transcript corresponding to ureG, and a transcript corresponding to ureR. These results indicate that expression of each of the plasmid-encoded urease genes is transcriptionally regulated in response to urea and suggest that there is autogenous regulation of ureR. Therefore UreR is one of three AraC family members described thus far that are positively auto-regulated.
Mol Microbiol 1995 Apr
PMID:UreR activates transcription at multiple promoters within the plasmid-encoded urease locus of the Enterobacteriaceae. 765 Nov 32

Urease is a virulence determinant, a taxonomic and diagnostic marker, and immunogen for Helicobacter pylori, an aetiologic agent of gastritis and peptic ulceration. This enzyme requires Ni2+ ions in the active site for successful hydrolysis of urea. When expressed in Escherichia coli, recombinant urease is only weakly active unless urease structural subunits are overexpressed, exogenous NiCl2 is added, and the host strain is grown in medium that does not chelate free Ni2+. As wild-type H. pylori does not require such conditions for very high levels of urease expression, we reasoned that additional genes were required to accumulate the metal ion. To isolate such genes, E. coli SE5000 (pHP808), which carries the H. pylori urease gene cluster, was complemented with a lambda ZAP-derived plasmid library of the H. pylori chromosome. One of 1000 ampicillin-resistant clones, plated onto urea segregation agar, produced detectable urease. Urease activity of this co-transformant, grown in Luria broth containing 1 microM NiCl2, was 36 mumol NH3 min-1 mg-1 protein. Urease-enhancing activity, which is not directly linked to the urease gene cluster, was localized by subcloning and nucleotide sequencing. The largest open reading frame, designated nixA, predicted a polypeptide of 34,317 Da that displayed characteristics of an integral membrane protein. In vitro transcription-translation of nixA sequences yielded a polypeptide estimated to be 32 kDa in size. An in-frame Bal31 deletion within nixA abolished urease-enhancing activity. At 50 nM NiCl2, E. coli containing the nixA clone transported 1250 +/- 460 pmol Ni2+ min-1 10(-8) cells, whereas the vector control transported only 140 +/- 85 pmol Ni2+ min-1 10(8) cells, i.e. significantly less (P = 0.01). We conclude that NixA confers upon E. coli a high-affinity nickel-transport system (KT = 11.3 +/- 2.4 nM; Vmax = 1750 +/- 220 pmol Ni2+ min-1 10(-8) cells) and is necessary for expression of catalytically active urease, regardless of growth conditions.
Mol Microbiol 1995 Apr
PMID:Helicobacter pylori nickel-transport gene nixA: synthesis of catalytically active urease in Escherichia coli independent of growth conditions. 765 Nov 42

All Helicobacter pylori isolates synthesize a 54 kDa immunodominant protein that was reported to be associated with the nickel-dependent urease of H. pylori. This protein was recently recognized as a homologue of the heat-shock protein of the GroEL class. The gene encoding the GroEL-like protein of H. pylori (HspB) was cloned (pILL689) and was shown to belong to a bicistronic operon including the hspA and hspB genes. In Escherichia coli, the constitutive expression of the hspA and hspB genes was initiated from a promoter located within an IS5 insertion element that mapped upstream to the two open reading frames (ORFs). IS5 was absent from the H. pylori genome, and was thus acquired during the cosmid cloning process. hspA and hspB encoded polypeptides of 118 and 545 amino acid residues, corresponding to calculated molecular masses of 13.0 and 58.2 kDa, respectively. Amino acid sequence comparison studies revealed that, although H. pylori HspA and HspB proteins were highly similar to their bacterial homologues, the H. pylori HspA featured a striking motif at the C-terminus. This unique motif consists of a series of cysteine and histidine residues resembling a nickel-binding domain, which is not present in any of the other bacterial GroES homologues so far characterized. When the pILL689 recombinant plasmid was introduced together with the H. pylori urease gene cluster (pILL763) into an E. coli host strain, an increase of urease activity was observed. This suggested a close interaction between the HspA and HspB proteins and the urease enzyme, and a possible role for HspA in the chelation of nickel ions. The genes encoding each of the HspA and HspB polypeptides were cloned, expressed independently as proteins fused to the maltose-binding protein (MBP) and purified in large scale. The MBP-HspA and MBP-HspB fusion proteins were shown to retain their antigenic properties. Both HspA and HspB represent antigens that are specifically recognized by the sera from H. pylori-infected patients. Whereas HspB was known to be immunogenic in humans, this is the first demonstration that HspA per se is also immunogenic.
Mol Microbiol 1994 Dec
PMID:Helicobacter pylori hspA-hspB heat-shock gene cluster: nucleotide sequence, expression, putative function and immunogenicity. 771 57

We sought to determine the genetic basis of expression of the ubiquitous (metabolic) urease of soybean. This isozyme is termed the metabolic urease because its loss, in eu4/eu4 mutants, leads to accumulation of urea, whereas loss of the embryo-specific urease isozyme does not. The eu4 lesion eliminated the expression of the ubiquitous urease in vegetative and embryonic tissues. RFLP analysis placed urease clone LC4 near, or within, the Eu4 locus. Sequence comparison of urease proteins (ubiquitous and embryo-specific) and clones (LC4 and LS1) indicated that LC4 and LS1 encode ubiquitous and embryo-specific ureases, respectively. That LC4 is transcribed into poly(A)+ RNA in all tissues was indicated by the amplification of its transcript by an LC4-specific PCR primer. (The LS1-specific primer, on the other hand, amplified poly(A)+ RNA only from developing embryos expressing the embryo-specific urease.) These observations are consistent with Eu4 being the ubiquitous urease structural gene contained in the LC4 clone. In agreement with this notion, the mutant phenotype of eu4/eu4 callus was partially corrected by the LC4 urease gene introduced by particle bombardment.
Mol Gen Genet 1994 Feb
PMID:A single gene (Eu4) encodes the tissue-ubiquitous urease of soybean. 790 65

The nickel metalloenzyme urease catalyses the hydrolysis of urea to ammonia and carbamate, and thus generates the preferred nitrogen source of many organisms. When produced by bacterial pathogens in either the urinary tract or the gastroduodenal region, urease acts as a virulence factor. At both sites of infection urease is known to enhance the survival of the infecting bacteria. Ammonia resulting from the action of urease is believed to increase the pH of the environment to one more favourable for growth, and to injure the surrounding epithelial cells. In addition, in the urinary tract urease activity can result in the formation of urinary calculi. Bacterial urease gene clusters contain from seven to nine genes depending upon the species. These genes encode the urease structural subunits and accessory polypeptides involved in the biosynthesis of the nickel metallocentre. So far, three distinct mechanisms of urease gene expression have been described for ureolytic bacteria. Some species constitutively produce urease; some species produce urease only if urea is present in the growth medium; and some species produce urease only during nitrogen-limiting growth conditions. For either the urea-inducible genes or the nitrogen-regulated genes transcription appears to be positively regulated. In the nitrogen-regulated systems, urease gene expression requires Nac (nitrogen assimilation control), a member of the LysR family of transcriptional activators. Urea dependent expression of urease requires UreR (urease regulator), a member of the AraC family of transcriptional activators. An evolutionary tree for urease genes of eight bacterial species is proposed.
Mol Microbiol 1993 Sep
PMID:Bacterial ureases: structure, regulation of expression and role in pathogenesis. 793 18

The genes encoding urease were cloned from Bordetella bronchiseptica and the 5.2 kb of DNA essential for expression analysed in a T7 RNA polymerase transcription-translation system. At least four polypeptides with predicted molecular weights of 69,000, 26,000, 12,200 and 11,000 were found. Partial DNA sequence of the gene encoding the 69,000 Da polypeptide revealed high amino acid identity to the alpha-subunit of Proteus mirabilis urease, UreC and jack bean urease. A stable, unmarked deletion was constructed in this gene to create a urease-negative mutant of B. bronchiseptica. To assess colonization in a guinea-pig model, the urease-negative strain was inoculated with the urease-positive parental strain in a mixed infection. The urease-negative strain out competed the urease-positive strain in the trachea, lungs and caecum. We demonstrate that urease is not essential for B. bronchiseptica colonization of the guinea-pig respiratory and digestive tracts.
Mol Microbiol 1993 Nov
PMID:Cloning of Bordetella bronchiseptica urease genes and analysis of colonization by a urease-negative mutant strain in a guinea-pig model. 796 32

Escherichia coli glutaminyl-tRNA synthetase (GlnRS) specifically recognizes nucleotides in the anticodon and acceptor stem of tRNA(Gln). Extensive conformational changes in the tRNA(Gln):GlnRS complex and requirement for tRNA in glutaminyl-adenylate formation suggests that accurate anticodon recognition is required for aminoacylation. A 17 amino acid loop in GlnRS (residues 476 to 492) that connects two beta-ribbon motifs was targeted for saturation mutagenesis as the motifs span the anticodon binding domain and extend to the active site. Opal suppressor tRNAs (GLN) derived from tRNA(Gln) are poor substrates for GlnRS, and compensating mutations in glnS (the structural gene for GlnRS) were selected by the ability of the mutant gene product to aminoacylate such a suppressor (GLNA3U70). A number of mutations in loop 476 to 492 were identified by genetic selection, and two of the GlnRS purified mutant enzymes showed elevated specificity constants (kcat/Km) for aminoacylation of a tRNA(Gln)-derived transcript with the opal (UCA) anticodon when compared with the wild-type enzyme. The specificity constants for the mutant enzymes with the cognate tRNA(Gln) transcript (anticodon CUG) were unchanged. Therefore, region 476 to 492 has been identified in communicating anticodon recognition with the active site at a distance of more than 30 A away, supporting a proposed model from the structure of the complex between tRNA(Gln):GlnRS. A previous study has identified residues that interact with the inside of the L-shaped tRNA as communicating accurate anticodon recognition. Therefore, at least two pathways of communication have been identified in the accurate recognition of tRNA by GlnRS.
J Mol Biol 1994 Jul 08
PMID:Connecting anticodon recognition with the active site of Escherichia coli glutaminyl-tRNA synthetase. 802 95

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