EC:3.1.30.2 - FACTA Search

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Query: EC:3.1.30.2 (endonuclease)
18,621 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ribonucleases O and Q, the two putative nucleolytic activities which we detected previously in the crude extract from a thermosensitive ribonuclease P mutant (TS241) of Escherichia coli and which were shown to function in the processing of tRNA precursors in vitro, were partially purified from the 1000000 x g supernatant fraction of E. coli Q13. In the course of purification of these enzymes, the total RNAs synthesized in the thermosensitive mutant at the restrictive temperature were used as the substrates and the activities were identified from disappearance or alteration of specific tRNA precursor molecules in polyacrylamide gel electrophoresis. The purified ribonuclease O preparation cleaved specifically the multimeric tRNA precursors at the spacer regions. The purified ribonuclease Q preparation removed, in accordance with the definition of this enzyme, extra nucleotides from the 3'-terminal ends of monomeric tRNA precursors. Some properties of these two nucleases were investigated. In addition to these nucleases, another exonuclease (tentatively designated ribonuclease Y) and ribonuclease P, a well-characterized endonuclease, were also purified. The sequential mode of the processing of tRNA precursors, originally observed in the cleavage reactions with the crude extracts in vitro, was supported by studies with the purified enzyme preparations.
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PMID:Specific ribonucleases involved in processing of tRNA precursors of Escherichia coli. Partial purification and some properties. 35 May 82

Extracts from interferon-treated, not virus infected EAT cells differ in several biochemical characteristics from extracts of untreated cells. Some of these differences are manifested only if the extracts are supplemented with ds RNA and ATP. Thus, in the extracts from interferon-treated cells these supplements activate a protein kinase and an endonuclease activity as well as an inhibitor of the translation of messenger RNA. The effect of the same supplements in extracts of untreated cells is much less pronounced. Other differences between the two types of extracts do not seem to depend on the addition of ds RNA and ATP. These include an impairment of mRNA cap methylation and an inhibition of peptide chain elongation that can be overcome by the addition of tRNA. The treatment of human (HeLa S3) cells with human interferon is manifested in the cell extract similarly to the treatment of EAT cells with mouse interferon. Studies are underway to isolate and characterize the ds RNA activated enzymes and the inhibitors and to establish how the presence of these in extracts from interferon-treated cells can account for the impairment of virus replication by interferon.
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PMID:Messenger RNA methylation, translation and degradation in extracts of interferon-treated cells. 35 50

We have made use of lysogens of a specialized transducing bacteriophage, lambdapyrG+ relA+, to select nonsense (relAnon) and insertion (relAins) mutations in the relA gene. Three independent relAnon mutants were isolated on the phage. In all three, the relaxed phenotype was suppressed by supD, supE, supF or sup6. Three independent relAins mutants were isolated, all containing an insertion element (probably IS2) in an apparently identical location in the relA gene. Polyacrylamide gel electrophoretic analysis of peptides synthesized by the phages in ultraviolet lightkilled host cells revealed that no stringent factor was coded for by either the relAins or relAnon phages (the latter in a sup+ cell); stringent factor was detected when the relAnon phages were used in a similar experiment with supD or supE host cells. The relAnon and relAins mutations could be crossed in haploid form in the E. coli chromosome. These recombinants grew with a normal doubling time, had a ppGpp pool which was between 70 and 100% compared with the classical relA strain, and underwent a normal carbon source shift-down. A restriction endonuclease map of the pyrG relA region of the specialized transducing phage is presented in which the position of the insertion element (recognized by a novel Hind III-cut site) defines the position of the relA gene. This position was verified by an analysis of the structure of five plasmids formed by cloning portions of the region in the pBR322 cloning vehicle. Our results indicate that the relA gene is not an essential cellular function, that there might be a second mechanism for the synthesis of basal level ppGpp in the cell and that the sole function of the relA gene is apparently the high level ppGpp synthesis triggered in response to deacylated tRNA.
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PMID:Nonsense and insertion mutants in the relA gene of E. coli: cloning relA. 36 54

We have employed S1 nuclease to probe the structure of an intermediate in tRNA biosynthesis available only in radiochemical purity. The dimeric precursor to tRNAGln and tRNALeu from bacteriophage T4 was digested with the single-strand specific nuclease, and the products of the reaction were compared with the S1 digestion products of the mature cognate tRNA'S. Quantitation and sequence analysis of the products revealed that the location and accessibility of S1 cleavage sites in the precursor were substantially identical with those in the mature forms. Based on these conclusions, it is argued that the dimer is comprised of two domains in which the specific features of both secondary and tertiary conformation closely resemble those found in the mature molecules; at the same time we noted small but apparently significant differences in certain regions of the molecule which may reflect signals for various maturation events. Finally, we have determined that the sites of precursor cleavage by RNase P, the endonuclease which generates the mature 5' termini of these tRNAs, were completely inaccessible to S1 digestion.
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PMID:S1 nuclease as a probe for the conformation of a dimeric tRNA precursor. 36 98

A DNA fragment of about 2000 base pairs carrying the gene for tRNA(1) (Ile) has been cloned from a total Eco RI endonuclease digest of Escherichia coli DNA. Sequence analyses revealed that about the first 850 base pairs from one end of the fragment contain a nucleotide sequence corresponding to that in the 3'-end of 16S rRNA. The gene for tRNA(Ile) follows the 16S rRNA gene and both genes flank a spacer sequence of 68 base pairs. The spacer region contains a repeating, a hair pin and a symmetrical structure when the sequence is viewed in the single stranded form. A notable hair pin structure is also observed in the region adjacent to the 3'-end of the tRNA(1) (Ile) gene. In addition, about 850 base pairs from the other end of the DNA fragment have been found to contain the nucleotide sequence of the 5'-end of 23S rRNA. The presence of the genes for tRNA(1) (Ile), 16S and 23S rRNA and the hybridization to tRNA(1) (Ala) suggest that this cloned DNA is part of one of the E. coli rRNA operons carrying these two tRNA genes as a spacer.Images
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PMID:Sequence of the gene for isoleucine tRNA1 and the surrounding region in a ribosomal RNA operon of Escherichia coli. 37 Jul 91

Chemical syntheses of the two dodecanucleotides d(T-C-A-A-C-G-T-A-A-C-A-C) and d(A-C-G-T-T-G-A-G-A-A-A-G), the two undecanucleotides d(T-T-T-A-C-A-G-C-G-G-C) and d(T-G-T-A-A-A-G-T-G-T-T), the decanucleotide d(A-G-T-C-C-G-A-A-A-G), and the nonanucleotide d(A-A-T-T-C-T-T-T-C) are described. These deoxyribo-oligonucleotide segments, excluding the decanucleotide, represent the DNA duplex corresponding to the previously determined nucleotide sequence -30 to -51 of the promoter region of the gene for the tyrosine suppressor tRNA (Sekiya, T., Gait, M.J., Norris, K., Ramamoorthy, B., and Khorana, H.G. (1976) J. Biol. Chem. 251, 4481-4489) and include the EcoRI restriction endonuclease sequence at the appropriate 5'-end. The nona- and decanucleotide along with the previously synthesized deoxyribo-oligonucleotide segments 25 to 27 (Ramamoorthy, B., Lees, R.G., Kleid, D., and Khorana, H.G. (1976) J. Biol. Chem. 251, 676-694) together represent the DNA duplex corresponding to the natural nucleotide sequence 121 to 142 of the region adjoining the C-C-A end of the tyrosine tRNA gene and, in addition, a run of nine nucleotides which include the EcoRI restriction enzyme sequence at the 5'-end. The syntheses used protected mono- and oligonucleotides and stepwise condensation methods. A noteworthy feature of the present syntheses was the use of reverse phase high pressure liquid chromatography for the rapid and efficient separation of synthetic reaction mixtures.
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PMID:Total synthesis of a tyrosine suppressor transfer RNA gene. XIV. Chemical synthesis of oligonucleotide segments corresponding to the terminal regions. 37 18

The chemically synthesized gene for Escherichia coli tyrosine suppressor tRNA has been joined to both plasmid (ColE1 ampr) and bacteriophage (Charon 3A) vector chromosomes after the latter had been digested with the restriction endonuclease EcoRI. Suppression of both bacterial (trpA, his, lacZ) and bacteriophage lambda amber mutations (Aam32, Bam1) has been demonstrated after transformation of E. coli with the recombinant DNA molecules carrying the synthetic suppressor tRNA gene. The cloned synthetic gene has been reisolated from the vector chromosomes after digestion of the latter with EcoRI restriction endonuclease and characterized in regard to its size and its ability to serve as a source of suppressor activity in further transformation experiments. This synthetic gene has also been shown to suppress bacterial amber mutations after it had been incorporated into the E. coli chromosome as part of a lambda prophage. Transcription, in vitro, of the cloned synthetic suppressor gene gave a product which, on treatment with a crude E. coli extract, afforded the tyrosine suppressor tRNA precursor. The latter was characterized by two-dimensional fingerprinting after digestion with T1-RNase. Exposure of the in vitro transcript to RNase P Selectively released the 41-nucleotide-long fragment characteristic of the 5'-end of the tRNA precursor. Thus, the nucleotide sequence of the cloned gene is accurate and its expression is controlled by its promoter.
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PMID:Total synthesis of a tyrosine suppressor tRNA gene. XVIII. Biological activity and transcription, in vitro, of the cloned gene. 37 20

The total synthesis of a tyrosine suppressor tRNA gene with a modified promoter is described. The alteration involves the replacement of the four G:C base pairs immediately preceding the start point of transcription by A:T base pairs. The new sequence contains the recognition sequence for the HindIII restriction endonuclease at the transcriptional start point, thus permitting fusion of the structural gene with promoters containing independent sequence modifications. The construction, cloning, and biological activity of several recombinant DNAs containing the tRNA gene with the modified promoter are described. The expression of this gene in vivo is compared with that of both the unmodified synthetic suppressor gene and a naturally occurring tyr su3+ gene cloned onto a multicopy plasmid.
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PMID:A synthetic tyrosine suppressor tRNA gene with an altered promoter sequence. Its cloning and relative expression in vivo. 38 55

A library of cloned yeast DNA fragments generated by digestion of yeast DNA with the restriction endonuclease Bam HI has been screened by colony hybridization to total yeast [32P]tRNA. Four hundred colonies carrying yeast tRNA genes were isolated. By hybridization to 125I-tRNALeu3, we have isolated from this collection 14 colonies carrying fragments containing yeast tRNALeu genes. The size of the yeast Bam HI inserts ranged from 2.45 x 10(6) to 14 x 10(6) daltons. One of these fragments was mapped in detail by restriction endonuclease digestion and hybridization to 125I-tRNALeu3. The presence of a tRNALeu3 gene was confirmed by DNA sequence. The results indicate that the tRNALeu3 coding region is not co-linear with the tRNALeu3. An intervening tract of 33 base pairs interrupts the coding sequences 1 base pair past the anticodon coding region. The putative structure of a tRNALeu3 precursor is deduced in which the anticodon base pairs with residues from the intervening sequence.
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PMID:Isolation of yeast tRNALeu genes. DNA sequence of a cloned tRNALeu3 gene. 38 86

Mitochondrial RNA (mtRNA) from petite yeast strains was analyzed by electrophoresis in agarose-urea, acrylamide-urea, and agarose-methyl mercuric hydroxide gels, and by transfer to diazobenzyloxy-methyl paper and hybridization to labeled mitochondrial DNA (mtDNA). Petites contain numerous mitochondrial transcripts, including processed species like 21 S and 14 S rRNA. Petite transcripts were found to fall into three classes: 1) bands that comigrate with grande mtRNA species; 2) "group-specific" new bands found in multiple strains and coinciding with specific regions of the mitochondrial genome; and 3) "strain-specific" new bands found only in individual petite strains. A deletion map was constructed in which we used the presence or absence of the first two types of mtRNA bands in specific strains, and the restriction endonuclease map of these strains. This map confirmed the localization of 21 S and 14 S rRNA, which were mapped previously by hybridization, and also localized more than 20 additional mtRNA species. The mtRNA species were grouped in regions of the genome in a fashion that strongly suggests that many of them are precursors to fully processed mtRNA species. Hybridization experiments with grande mtRNA and cloned mtDNA fragments have shown the same kind of transcript grouping. Other hybridization experiments have demonstrated two apparent precursors to 21 S rRNA (3700 nucleotides) measuring 5500 and 4500 nucleotides. Processed tRNAs are found only in petites that contain a specific region of the genome near the P (paromomycin resistance) locus. When this region is absent, processed tRNAs are not detected, even for tRNA genes quite distant from the P locus. Since this phenotype is expressed in petites that lack mitochondrial protein synthesis, and since it maps to a specific location in the mitochondrial genome, there appears to be a mtRNA species which has a role in processing of mitochondrial tRNA.
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PMID:Transcription, processing, and mapping of mitochondrial RNA from grande and petite yeast. 38 87

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