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)

Wild-type Escherichia coli glutaminyl-tRNA synthetase (GlnRS; EC 6.1.1.18) poorly aminoacylates opal suppressors (GLN) derived from tRNA(Gln). Mutations in glnS (the gene encoding GlnRS) that compensate for impaired aminoacylation were isolated by genetic selection. Two glnS mutants were obtained by using opal suppressors differing in the nucleotides composing the base pair at 3.70: glnS113 with an Asp-235-->Asn change selected with GLNA3U70 (GLN carrying G3-->A and C70-->U changes), and glnS114 with a Gln-318-->Arg change selected with GLNU70 (GLN carrying a C70-->U change). The Asp-235-->Asn change was identified previously by genetic selection. Additional mutants were isolated by site-directed mutagenesis followed by genetic selection; the mutant enzymes have single amino acid changes (Lys-317-->Arg and Gln-318-->Lys). A number of mutants with no phenotype also were obtained randomly. In vitro aminoacylation of a tRNA(Gln) transcript by GlnRS enzymes with Lys-317-->Arg, Gln-318-->Lys, or Gln-318-->Arg changes shows that the enzyme's kinetic parameters are not greatly affected by the mutations. However, aminoacylation of a tRNA(Gln) transcript with an opal (UCA) anticodon shows that the specificity constants (kcat/Km) for the mutant enzymes were 5-10 times above that of the wild-type GlnRS. Interactions between Lys-317 and Gln-318 with the inside of the L-shaped tRNA and with the side chain of Gln-234 provide a connection between the acceptor end-binding and anticodon-binding domains of GlnRS. The GlnRS mutants isolated suggest that perturbation of the interactions with the inside of the tRNA L shape results in relaxed anticodon recognition.
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PMID:Functional communication in the recognition of tRNA by Escherichia coli glutaminyl-tRNA synthetase. 750 18

The CCA trinucleotide is a universally conserved feature of the 3' end of tRNAs, where it serves as the site of amino acid attachment. Despite this extreme conservation, we have isolated functional mutants of tRNA(His) and tRNA(Val1) with altered CCA ends. A mutant that leads to de-repression of the histidine biosynthetic operon in Salmonella typhimurium has been characterized and found to have the CCA end of the sole tRNA(His) species mutated to UCA. However, constructed mutants of tRNA(His) with ACA or GCA ends appeared to be nonfunctional in vivo. Mutants of Escherichia coli tRNA(Val1) with GCA or ACA ends were isolated on the basis of their ability to promote frameshifting at a specific sequence. These same tRNA(Val1) mutants also caused read-through of stop codons that were one, or in some instances two, codons downstream of the valine codon decoded by the mutant tRNA. A startling implication of these data is that disruption of interactions between the CCA end of the tRNA and the large ribosomal subunit promotes these aberrant codon-anticodon interactions on the small ribosomal subunit.
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PMID:Functional tRNAs with altered 3' ends. 768 77

Peptidyl transfer is a key step in the process of protein biosynthesis. To examine the role of the universal CCA terminal sequence of tRNA in the process of peptidyl transfer, various mutant transcripts of Escherichia coli valine tRNA were constructed. Peptidyl transferase activity, monitored by the 'fragment reaction' with a slight modification, was decreased by mutation at any one base of CCA. The effect of mutation was moderate in the UCA, CUA and CCG mutants. Replacement of A76 by a pyrimidine nucleotide, or replacement of either C74 or C75 by a purine nucleotide caused a marked decrease in the activity. These findings suggested that the universal CCA terminus of tRNA makes a functional interaction with ribosomal RNA by base-pairing.
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PMID:The role of the CCA sequence of tRNA in the peptidyl transfer reaction. 792 46

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.
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PMID:Connecting anticodon recognition with the active site of Escherichia coli glutaminyl-tRNA synthetase. 802 95

We have developed a simple, rapid and sensitive assay for tRNA gene expression in plant cells. A plant tRNA(Leu) gene was site-specifically mutated to encode each of the three anticodon sequences (CUA, UUA and UCA) that recognize, respectively, the amber, ochre and opal stop codons. The suppression activity of these genes was detected by their ability to restore transient beta-glucuronidase (GUS) expression in tobacco protoplasts electroporated with GUS genes containing premature stop codons. Protoplasts co-electroporated with the amber suppressor tRNA gene and a GUS gene containing a premature amber stop codon showed up to 20-25% of the activity found in protoplasts transfected with the functional control GUS gene. Ochre and opal suppressors presented maximum efficiencies of less than 1%. This system could be adapted to examine transcription, processing or aminoacylation of tRNAs in plant cells. In addition, phenotypically normal, fertile tobacco plants expressing a stably incorporated amber suppressor tRNA gene have been obtained. This suppressor tRNA can be used to transactivate a target gene containing a premature amber stop codon by a factor of at least several hundred-fold.
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PMID:Transfer RNA-mediated suppression of stop codons in protoplasts and transgenic plants. 834 3

Unmodified tRNA molecules are useful for many purposes in cell-free protein biosynthesis, but there is little information about how the lack of tRNA post-transcriptional modifications affects the coding specificity for synonymous codons. In the present study, we prepared an unmodified form of Escherichia coli tRNA1Ser, which originally has the cmo5UGA anticodon (cmo5U = uridine 5-oxyacetic acid) and recognizes the UCU, UCA and UCG codons. The codon specificity of the unmodified tRNA was tested in a cell-free protein synthesis directed by designed mRNAs under competition conditions with the parent tRNA1Ser. It was found that the unmodified tRNA with the UGA anti-codon recognizes the UCA codon nearly as efficiently as the modified tRNA. The unmodified tRNA recognized the UCU codon with low, but detectable efficiency, whereas no recognition of the UCC and UCG codons was detected. Therefore, the absence of modifications makes this tRNA more specific to the UCA codon by remarkably reducing the efficiencies of wobble reading of other synonymous codons, without a significant decrease in the UCA reading efficiency.
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PMID:Codon-reading specificity of an unmodified form of Escherichia coli tRNA1Ser in cell-free protein synthesis. 876 Aug 70

Selenocysteine is recognized as the 21st amino acid in ribosome-mediated protein synthesis and its specific incorporation is directed by the UGA codon. Unique tRNAs that have complementary UCA anticodons are aminoacylated with serine, the seryl-tRNA is converted to selenocysteyl-tRNA and the latter binds specifically to a special elongation factor and is delivered to the ribosome. Recognition elements within the mRNAs are essential for translation of UGA as selenocysteine. A reactive oxygen-labile compound, selenophosphate, is the selenium donor required for synthesis of selenocysteyl-tRNA. Selenophosphate synthetase, which forms selenophosphate from selenide and ATP, is found in various prokaryotes, eukaryotes, and archaebacteria. The distribution and properties of selenocysteine-containing enzymes and proteins that have been discovered to date are discussed. Artificial selenoenzymes such as selenosubtilisin have been produced by chemical modification. Genetic engineering techniques also have been used to replace cysteine residues in proteins with selenocysteine. The mechanistic roles of selenocysteine residues in the glutathione peroxidase family of enzymes, the 5' deiodinases, formate dehydrogenases, glycine reductase, and a few hydrogenases are discussed. In some cases a marked decrease in catalytic activity of an enzyme is observed when a selenocysteine residue is replaced with cysteine. This substitution caused complete loss of glycine reductase selenoprotein A activity.
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PMID:Selenocysteine. 881 Nov 75

Effects of a single nucleoside modification at the first position of the anticodon of a transfer RNA molecule on its codon reading properties were investigated by use of a cell-free protein synthesis. We prepared two artificial tRNA molecules that differ only in the nucleotide at the first position of the anticodon. One has an unmodified uridine and the other has a 5-methoxyuridine (mo5U). These molecules were charged with labeled serine and introduced into a cell-free protein synthesis directed by a designed mRNA, and the relative codon reading efficiencies were calculated. The results showed that the modification of U into mo5U elevates the reading efficiencies of the UCU and UCG codons but reduces that of the UCA codon.
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PMID:Codon recognition by tRNA molecules with a modified or unmodified uridine at the first position of the anticodon. 884 23

Deviations from the universal genetic code have evolved independently several times in ciliated protozoa. Thus, in some species UAA and UAG are no longer used as termination codons, but are read as glutamine, whereas in the genus Euplotes , UGA is translated as cysteine. We have investigated the nature of the tRNACys isoacceptor responsible for decoding UGA in Euplotes cells. Southern hybridization analyses indicated that a single DNA molecule of 630 bp encoding tRNACys exists in the macronucleus of Euplotes octocarinatus . Cloning and sequencing of this fragment revealed that it contains only one copy of a tRNACys gene, which codes for a normal tRNACys with GCA anticodon. This is the first report of the characterization of a tRNA gene in any hypotrichous ciliate. It contains putative signals for initiation and termination of transcription by RNA polymerase III and can be transcribed efficiently in vitro in HeLa cell nuclear extract. Intensive studies on the DNA and tRNA level involving PCR analyses have not disclosed the existence of any tRNA Cys isoacceptor with UCA or ICA anticodons. Translation of the UGA codon by tRNA sub GCA sup Cys necessitates a G:A mispairing in the first anticodon position. We discuss a number of aspects which might contribute to the finding that a near-cognate tRNA isoacceptor efficiently translates the UGA stop codon.
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PMID:The hypotrichous ciliate Euplotes octocarinatus has only one type of tRNACys with GCA anticodon encoded on a single macronuclear DNA molecule. 975 21

The kinetics and efficiency of decoding of the UGA of a bacterial selenoprotein mRNA with selenocysteine has been studied in vivo. A gst-lacZ fusion, with the fdhF SECIS element ligated between the two fusion partners, gave an efficiency of read-through of 4-5%; overproduction of the selenocysteine insertion machinery increased it to 7-10%. This low efficiency is caused by termination at the UGA and not by translational barriers at the SECIS. When the selenocysteine UGA codon was replaced by UCA, and tRNASec with anticodon UGA was allowed to compete with seryl-tRNASer1 for this codon, selenocysteine was found in 7% of the protein produced. When a non-cognate SelB-tRNASec complex competed with EF-Tu for a sense codon, no effects were seen, whereas a non-cognate SelB-tRNASec competing with EF-Tu-mediated Su7-tRNA nonsense suppression of UGA interfered strongly with suppression. The induction kinetics of beta-galactosidase synthesis from fdhF'-'lacZ gene fusions in the absence or presence of SelB and/or the SECIS element, showed that there was a translational pause in the fusion containing the SECIS when SelB was present. The results show that decoding of UGA is an inefficient process and that using the third dimension of the mRNA to accommodate an additional amino acid is accompanied by considerable quantitative and kinetic costs.
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PMID:Dynamics and efficiency in vivo of UGA-directed selenocysteine insertion at the ribosome. 1020 81

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