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Query: UNIPROT:P06889 (Mol)
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To identify trans-acting factors involved in mRNA decay in the yeast Saccharomyces cerevisiae, we have begun to characterize conditional lethal mutants that affect mRNA steady-state levels. A screen of a collection of temperature-sensitive mutants identified ts352, a mutant that accumulated moderately stable and unstable mRNAs after a shift from 23 to 37 degrees C (M. Aebi, G. Kirchner, J.-Y. Chen, U. Vijayraghavan, A. Jacobson, N.C. Martin, and J. Abelson, J. Biol. Chem. 265:16216-16220, 1990). ts352 has a defect in the CCA1 gene, which codes for tRNA nucleotidyltransferase, the enzyme that adds 3' CCA termini to tRNAs (Aebi et al., J. Biol. Chem., 1990). In a shift to the nonpermissive temperature, ts352 (cca1-1) cells rapidly cease protein synthesis, reduce the rates of degradation of the CDC4, TCM1, and PAB1 mRNAs three- to fivefold, and increase the relative number of ribosomes associated with mRNAs and the overall size of polysomes. These results were analogous to those observed for cycloheximide-treated cells and are generally consistent with models that invoke a role for translational elongation in the process of mRNA turnover.
Mol Cell Biol 1992 Dec
PMID:A mutation in the tRNA nucleotidyltransferase gene promotes stabilization of mRNAs in Saccharomyces cerevisiae. 144 5

The sequence of the PcnB protein of Escherichia coli, a protein required for copy number maintenance of ColE1-related plasmids, was compared with the PIR sequence database. Strong local similarities to the sequence of the E. coli protein tRNA nucleotidyltransferase were found. Since a substrate of the latter protein, tRNA, structurally resembles the RNAs that control ColE1 copy number we believe that we may have identified a region in PcnB that interacts with these RNAs. Consistent with this idea is our observation that PcnB is required for the replication of R1, a plasmid whose replication is also regulated by a small RNA.
Mol Gen Genet 1990 Jan
PMID:A possible role for the pcnB gene product of Escherichia coli in modulating RNA: RNA interactions. 169 35

We have recently described the properties of a wheat mitochondrial extract that is able to process, accurately and efficiently, artificial transcripts containing wheat mitochondrial tRNA sequences, with the production of mature tRNAs (P.J. Hanic-Joyce and M.W. Gray, J. Biol. Chem., in press). Such processing involves 5'-endonucleolytic, 3'-endonucleolytic, and tRNA nucleotidyltransferase activities. Here we show that this system also acts on transcripts containing sequences corresponding to an unusual class of short repeats ('t-elements') in wheat mtDNA. These repeats are theoretically capable of assuming a tRNA-like secondary structure, although stable transcripts corresponding to them are not detectable in vivo. We find that t-element sequences are processed with the same specificity and with comparable efficiency as are authentic tRNA sequences. Because known t-elements are located close to and in the same transcriptional orientation as active genes (18S-5S, 26S, tRNA(Pro)) in wheat mtDNA, our results raise the question of whether t-elements play a role in gene expression in wheat mitochondria.
Plant Mol Biol 1990 Oct
PMID:In vitro processing of transcripts containing novel tRNA-like sequences ('t-elements') encoded by wheat mitochondrial DNA. 210 74

Recognition of tRNA by the enzyme ATP/CTP:tRNA nucleotidyltransferase from rabbit liver was studied using 12 tRNAs, previously treated with the chemical modifier diethylpyrocarbonate (DEP). Such chemically modified tRNAs were labeled with 32P by nucleotidyltransferase, using alpha-[32P]ATP as a cosubstrate. A carbethoxylated purine at position 57 in the psi-loop interfered with recognition of the tRNA in all instances. DEP-modified purines at other positions (58 in the psi-loop, 52 or 53 in the psi-stem, and 71-73 in the acceptor stem), also interfered with the interaction, but in only a few tRNAs. The mammalian enzyme was more similar to the homologous enzyme from yeast than that from bacteria, in its requirements for chemically unmodified purines. The extent of exclusion of modified bases from 32P-labeled material diminished as the concentration of enzyme increased, demonstrating that interference was not due to the inability of the chemically altered tRNA to refold into a recognizable conformation. The degree of purification of the enzyme did not affect the identity of bases that inhibited the reaction when modified.
J Mol Recognit 1990 Aug
PMID:Purines in tRNAs required for recognition by ATP/CTP:tRNA nucleotidyltransferase from rabbit liver. 227 31

A survey of RNases in Xenopus laevis oocytes has been carried out to identify potential tRNA-processing enzymes in this system. Using a variety of specific and nonspecific substrates, we have shown that oocytes contain multiple RNases with various specificities. Three activities that could cleave the extraneous residues from the artificial tRNA precursor, tRNA-C-[14C]U-C, to generate a substrate for -C-C-A addition by tRNA nucleotidyltransferase were identified. One of these was a cytoplasmic exonuclease which generated predominantly tRNA-C, whereas the other two were nuclear endonucleases which cleaved the precursor to generate tRNA-N. The possible involvement of these activities in 3' tRNA processing in oocytes is discussed.
Mol Cell Biol 1983 Oct
PMID:Identification of multiple RNases in Xenopus laevis oocytes and their possible role in tRNA processing. 664 19

The ability of yeast extracts to aminoacylate crude yeast tRNA with leucine and other amino acids is largely lost after chromatography of the extracts in DEAE-Sephadex. The original aminoacylating ability is restored by combining protein fractions from the DEAE-chromatogram. The characteristics of this reactivation are very similar to the activation, by protein factors, of certain aminoacyl-tRNA synthetases reported by others. The results in this work indicate that the apparent aminoacyl-tRNA synthetase activator factor is the tRNA nucleotidyltransferase and that the restoration of the original tRNA aminoacylating ability is a consequence of the repairing of the 3' end of incomplete tRNA chains.
Mol Cell Biochem 1983
PMID:Identification of an apparent aminoacyl-tRNA synthetase activator factor as tRNA nucleotidyltransferase. 685 46

ATP (CTP):tRNA nucleotidyltransferase (EC 2.7.7.25) was purified to apparent homogeneity from a crude extract of Lupinus albus seeds. Purification was accomplished using a multistep protocol including ammonium sulfate fractionation and chromatography on anion-exchange, hydroxylapatite and affinity columns. The lupin enzyme exhibited a pH optimum and salt and ion requirements that were similar to those of tRNA nucleotidyltransferases from other sources. Oligonucleotides, based on partial amino acid sequence of the purified protein, were used to isolate the corresponding cDNA. The cDNA potentially encodes a protein of 560 amino acids with a predicted molecular mass of 64 164 Da in good agreement with the apparent molecular mass of the pure protein determined by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The size and predicted amino acid sequence of the lupin enzyme are more similar to the enzyme from yeast than from Escherichia coli with some blocks of amino acid sequence conserved among all three enzymes. Functionality of the lupin cDNA was shown by complementation of a temperature-sensitive mutation in the yeast tRNA nucleotidyltransferase gene. While the lupin cDNA compensated for the nucleocytoplasmic defect in the yeast mutant it did not enable the mutant strain to grow at the non-permissive temperature on a non-fermentable carbon source.
Plant Mol Biol 1996 Jan
PMID:Purification and characterization of a tRNA nucleotidyltransferase from Lupinus albus and functional complementation of a yeast mutation by corresponding cDNA. 861 52

A phosphate-dependent exonuclease activity was identified in purified protein fractions from Bacillus subtilis that were selected for binding to poly(I)-poly(C) agarose. Based on the characteristics of the degradation products and the absence of this activity in a pnpA strain, which contains a transposon insertion in the B. subtilis PNPase gene (Luttinger et al., 1996--accompanying paper), this exonuclease activity was shown to be due to polynucleotide phosphorylase (PNPase). Processive 3'-to-5' exonucleolytic degradation of an SP82 phage RNA substrate was stalled at a particular site. Structure probing of the RNA showed that the stall site was downstream of a particular stem-loop structure. A similar stall site was observed for an RNA that comprised the intergenic region between the B. subtilis rpsO and pnpA genes. The ability to initiate degradation of a substrate that had a stem structure at its 3' end differed for the B. subtilis and Escherichia coli PNPase enzymes.
Mol Microbiol 1996 Jan
PMID:In vitro processing activity of Bacillus subtilis polynucleotide phosphorylase. 882 78

The protein sequence of ATP/CTP:tRNA nucleotidyltransferase (cca) from Sulfolobus shibatae was used to search open reading frames in the genome of Methanococcus jannaschii. Translations of two unidentified open reading frames showed significant sequence similarity to portions of the Sulfolobus cca protein. When the two open reading frames were joined together, the expanded open reading frame was similar in sequence to the entire Sulfolobus cca protein and displayed features of the active site signature sequence proposed for members of class I enzymes within the superfamily of nucleotidyltransferases (Yue et al., 1996, RNA 2, 895-908). A possible UUG start codon was identified based on significant sequence similarity of the resulting amino-terminal region to that of Sulfolobus, and on a six-base complementarity between an adjacent upstream sequence and Methanococcus 16S rRNA.
J Mol Evol 1997 Jun
PMID:Unidentified open reading frames in the genome of Methanococcus jannaschii are similar in sequence to an archaebacterial gene for tRNA nucleotidyltransferase. 916 62

We mapped and cloned SKI6 of Saccharomyces cerevisiae, a gene that represses the copy number of the L-A double-stranded RNA virus, and found that it encodes an essential 246-residue protein with homology to a tRNA-processing enzyme, RNase PH. The ski6-2 mutant expressed electroporated non-poly(A) luciferase mRNAs 8- to 10-fold better than did the isogenic wild type. No effect of ski6-2 on expression of uncapped or normal mRNAs was found. Kinetics of luciferase synthesis and direct measurement of radiolabeled electroporated mRNA indicate that the primary effect of Ski6p was on efficiency of translation rather than on mRNA stability. Both ski6 and ski2 mutants show hypersensitivity to hygromycin, suggesting functional alteration of the translation apparatus. The ski6-2 mutant has normal amounts of 40S and 60S ribosomal subunits but accumulates a 38S particle containing 5'-truncated 25S rRNA but no 5.8S rRNA, apparently an incomplete or degraded 60S subunit. This suggests an abnormality in 60S subunit assembly. The ski6-2 mutation suppresses the poor expression of the poly(A)- viral mRNA in a strain deficient in the 60S ribosomal protein L4. Thus, a ski6 mutation bypasses the requirement of the poly(A) tail for translation, allowing better translation of non-poly(A) mRNA, including the L-A virus mRNA which lacks poly(A). We speculate that the derepressed translation of non-poly(A) mRNAs is due to abnormal (but full-size) 60S subunits.
Mol Cell Biol 1998 May
PMID:Ski6p is a homolog of RNA-processing enzymes that affects translation of non-poly(A) mRNAs and 60S ribosomal subunit biogenesis. 956 88


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