EC:3.1.31.1 - FACTA Search

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Query: EC:3.1.31.1 (micrococcal nuclease)
2,818 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

After treatment at a microsomal nuclease concentration too low to reduce the endogenous amino acid-incorporating activity of freshly prepared reticulocyte lysate, there is little, if any, intact 26 S RNA left in the ribosomes of either wheat germ or rabbit reticulocyte cell-free protein synthesizing extracts. The primary scissions, probably at highly exposed sites in the rRNA of plant and animal ribosomes, produce two fragments which remain complexed until thermal denaturation reveals "hidden breaks." Molecular weights of the fragments are approximately 0.5 x 10(6) and 0.8 x 10(6) in the case of wheat, and 0.4 x 10(6) and 1.3 x 10(6) in the case of rabbit. There is little perceptible degradation of 5 S, 5.8 S, and 18 S rRNA, or of tRNA in the same extracts. Even though limited degradation of 26 S rRNA by a reticulocyte nuclease has been reported to severely impair the translational mechanism in reticulocyte ribosomes, micrococcal nuclease-induced degradation of rRNA, whether limited or extensive, does not seriously impair the ability of reticulocyte lysates to discriminate, by selective polypeptide synthesis, between complex populations of cellular mRNA. In an allied study, it is shown that under conditions well suited to recovery of the 5.8 S/26 S rRNA complex, with its naturally occurring hidden break, 5 S/18 S rRNA complexing is not detectable in the RNA or metabolizing embryos, nor in the RNA from untreated or nuclease-treated protein synthesizing extracts from wheat and rabbit. The significance of this finding is briefly elaborated in relation to the suggestion that 5 S rRNA may interact with the M2(6)A-m2(6)A hairpin near the 3'-end of 18 S rRNA.
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PMID:Structural integrity of DNA and translational integrity of ribosomes in nuclease-treated cell-free protein synthesizing systems prepared from wheat germ and rabbit reticulocytes. 724 Jan 74

The remarkable resistance of isolated ribosomes to gelonin is overcome by cofactors present in post-ribosomal supernatants. In rat liver post-ribosomal supernatant RNA is the cofactor responsible of the sensitization of ribosomes. Isolated RNA, which consists mostly of deacylated tRNA, accounts for less than 10 per cent of the activity of the original supernatant. The activity of the supernatant is completely destroyed by micrococcal nuclease and RNAase A and also by proteinase K, suggesting that some protein enhances the effect of RNA. RNA has a role also in the sensitization of ribosomes to alpha-sarcin, an RNAase which inactivates ribosomes by hydrolyzing a single phosphodiester bond in the same region of 28S rRNA which is the target of the N-glycosidase activity of gelonin.
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PMID:RNA present in post-ribosomal supernatants makes ribosomes susceptible to inactivation by gelonin and alpha-sarcin. 751 79

A biosynthetic method has been developed that makes possible the site-specific incorporation of a large number of amino acids and analogues within proteins. In this approach, an amber suppressor tRNA chemically aminoacylated with the desired amino acid incorporates this amino acid site specifically into a protein in response to an amber codon introduced at the corresponding position in the protein's DNA sequence. Using this method, precise changes within a protein can be made to address detailed structure-function questions. A series of fluorinated tyrosine analogues and linear, branched, and cyclic hydrophobic amino acids have been used to determine the impact of hydrogen bonding and hydrophobic packing, respectively, on protein stability. Glutamate analogues and conformationally restricted amino acids have been used to probe the mechanisms of staphylococcal nuclease and ras. In addition, this technique has been used to construct photocaged proteins and proteins containing photoaffinity labels, spin labels, and isotopic labels at specific positions in the protein sequence suitable for biophysical studies.
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PMID:Site-directed mutagenesis with an expanded genetic code. 766 23

Ribonuclease P (RNase P) from Dictyostelium discoideum has been purified 470-fold. D. discoideum RNase P cleaves the precursor to Schizosaccharomyces pombe suppressor tRNA(Ser) at the same site as S. pombe RNase P, producing the mature 5' end of tRNA(Ser). pH and temperature optima for enzyme activity are 7.6 and 37 degrees C, respectively. The enzyme shows optimal activity in the presence of 5 mM MgCl2 and 10 mM NH4Cl or 5 mM KCl. The apparent Km for the S. pombe tRNA precursor derived from the supS1 tRNA(Ser) gene is 240 nM, and the apparent Vmax is 3.6 pmol/min. Inhibition of D. discoideum RNase P by proteinase K and micrococcal nuclease strongly indicates that the activity requires both protein and RNA components. In cesium sulfate density gradients, the enzyme has a buoyant density of 1.23 g/ml, indicating a low RNA/protein ratio for the holoenzyme.
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PMID:Partial purification and characterization of RNase P from Dictyostelium discoideum. 773 3

Two distinct RNase P-like activities which cleave leader sequences from pre-tRNA molecules to give mature 5' ends have been identified in carrot suspension-culture cells. An Escherichia coli pre-tRNA(Phe) and a tobacco pre-tRNA(Tyr) were transcribed in vitro then used as substrates for processing reactions in a cell-free extract. The pre-tRNA(Tyr) transcript was used to establish optimal salt and divalent cation requirements for processing. Kinetic experiments were then carried out on both substrates to determine if 5' and 3' processing were ordered. Primer extension analysis of processing intermediates and stable products verified that an ammonium sulfate fraction of the extract was indeed capable of accurately processing the 5' ends of both pre-tRNAs. Subsequent fractionation of the 5' end-processing activity by chromatography on phosphocellulose revealed two distinct activities, eluting at 0.1 and 0.5 M KCI, when assayed with the tobacco pre-tRNA(Tyr) substrate. When the same fractions were assayed with the E. coli pre-tRNA(Phe), only the 0.1 M KCI fraction exhibited activity. Both of the active fraction display sensitivity to micrococcal nuclease (MN) and proteinase K indicating each is a ribonucleoprotein, a result not seen with other plant RNase Ps. Subsequent FPLC fractionation of the two activities using Mono Q and Mono S columns demonstrated that the two activities could be further distinguished on the basis of their chromatographic behavior.
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PMID:Characterization and partial purification of two pre-tRNA 5'-processing activities from Daucus carrota (carrot) suspension cells. 774 55

The Saccharomyces cerevisiae U6 RNA gene (SNR6), which is transcribed by RNA polymerase III, has an unusual combination of promoter elements: an upstream TATA box, an intragenic A block, and a downstream B block. In tRNA genes, the A and B blocks are binding sites for the transcription initiation factor TFIIIC, which positions TFIIIB a fixed distance upstream of the A block. However, in vitro transcription of SNR6 with purified components requires neither TFIIIC nor the A and B blocks, presumably because TFIIIB recognizes the upstream sequences directly. Here we demonstrate that TFIIIB placement on SNR6 in vivo is directed primarily by the TFIIIC-binding elements rather than by upstream sequences. We show that the A block is a stronger start site determinant than the upstream sequences when the two are uncoupled by an insertion mutation. Furthermore, while TFIIIC-independent in vitro transcription of SNR6 is highly sensitive to TATA box point mutations, in vivo initiation on SNR6 is only marginally sensitive to such mutations unless the A block is mutated. Intriguingly, a deletion downstream of the U6 RNA coding region that reduces A-to-B block spacing also increases in vivo dependence on the TATA box. Moreover, this deletion results in the appearance of micrococcal nuclease-hypersensitive sites in the TFIIIB chromatin footprint, indicating that TFIIIB binding is disrupted by a mutation 150 bp distant. This and additional chromatin footprinting data suggest that SNR6 is assembled into a nucleoprotein complex that facilitates the TFIIIC-dependent binding of TFIIIB.
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PMID:TFIIIB placement on a yeast U6 RNA gene in vivo is directed primarily by TFIIIC rather than by sequence-specific DNA contacts. 786 39

The mitochondrial genome of trypanosomes, unlike that of most other eukaryotes, does not appear to encode any tRNAs. Therefore, mitochondrial tRNAs must be either imported into the organelle or created through a novel mitochondrial process, such as RNA editing. Trypanosomal tRNA(Tyr), whose gene contains an 11-nucleotide intron, is present in both the cytosol and the mitochondrion and is encoded by a single-copy nuclear gene. By site-directed mutagenesis, point mutations were introduced into this tRNA gene, and the mutated gene was reintroduced into the trypanosomal nuclear genome by DNA transfection. Expression of the mutant tRNA led to the accumulation of unspliced tRNA(Tyr) (A. Schneider, K. P. McNally, and N. Agabian, J. Biol. Chem. 268:21868-21874, 1993). Cell fractionation revealed that a significant portion of the unspliced mutant tRNA(Tyr) was recovered in the mitochondrial fraction and was resistant to micrococcal nuclease treatment in the intact organelle. Expression of the nuclear integrated, mutated tRNA gene and recovery of its gene product in the mitochondrial fraction directly demonstrated import. In vitro experiments showed that the unspliced mutant tRNA(Tyr), in contrast to the spliced wild-type form, was no longer a substrate for the cognate aminoacyl synthetase. The presence of uncharged tRNA in the mitochondria demonstrated that aminoacylation was not coupled to import.
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PMID:A nuclear encoded tRNA of Trypanosoma brucei is imported into mitochondria. 813 37

A novel folding motif has been observed in four different proteins which bind oligonucleotides or oligosaccharides: staphylococcal nuclease, anticodon binding domain of asp-tRNA synthetase and B-subunits of heat-labile enterotoxin and verotoxin-1. The common fold of the four proteins, which we call the OB-fold, has a five-stranded beta-sheet coiled to form a closed beta-barrel. This barrel is capped by an alpha-helix located between the third and fourth strands. The barrel-helix frameworks can be superimposed with r.m.s. deviations of 1.4-2.2 A, but no similarities can be observed in the corresponding alignment of the four sequences. The nucleotide or sugar binding sites, known for three of the four proteins, are located in nearly the same position in each protein: on the side surface of the beta-barrel, where three loops come together. Here we describe the determinants of the OB-fold, based on an analysis of all four structures. These proposed determinants explain how very different sequences adopt the OB-fold. They also suggest a reinterpretation of the controversial structure of gene 5 ssDNA binding protein, which exhibits some topological and functional similarities with the OB-fold proteins.
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PMID:OB(oligonucleotide/oligosaccharide binding)-fold: common structural and functional solution for non-homologous sequences. 845 42

Ribonuclease P (RNase P) is responsible for the generation of mature 5' termini of tRNA. The RNA component of this complex encodes the enzymatic activity in bacteria and is itself catalytically active under appropriate conditions in vitro. The role of the subunits in eucaryotes has not yet been established. We have partially purified RNase P activity from the ciliate protozoan Tetrahymena thermophila to learn more about the biochemical characteristics of RNase P from a lower eucaryote. The Tetrahymena RNase P displays a pH optimum and temperature optimum characteristic of RNase P enzymes isolated from other organisms. The Km of the T. thermophila enzyme for pre-tRNAGln is 1.6 x 10(-7)M, which is comparable to the values reported for other examples of RNase P. The Tetrahymena RNase P is a ribonucleoprotein complex, as supported by its sensitivity to micrococcal nuclease and proteinase K. The buoyant density of the enzyme in Cs2SO4 is 1.42 g/ml, which suggests that the RNA component of the Tetrahymena enzyme comprises a significantly greater percentage of the holoenzyme than that determined for RNase P of other Eucarya or Archaea. The holoenzyme has a requirement for divalent cations displaying characteristics that are unique for RNase P but closely resemble preferences reported for the Tetrahymena group I intron RNA. Puromycin inhibits pre-tRNA processing by the Tetrahymena complex, and implications of the similarities between recognition of tRNA by ribosomal components and RNase P are discussed.
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PMID:Ribonuclease P of Tetrahymena thermophila. 866 80

RNase P is a ribonucleoprotein endoribonuclease responsible for the 5' maturation of precursor tRNAs in all organisms. While analyzing mutations in conserved positions of the yeast nuclear RNase P RNA subunit, significant accumulation of an aberrant RNA of approximately 193 nucleotides was observed. This abundant RNA was identified as a 3'extended form of the 5.8S rRNA. This strain also displays a slightly elevated level of other rRNA processing intermediates with 5-ends at processing site A2 in the internal transcribed spacer 1 (ITS1) region of the rRNA primary transcript. To test whether pre-rRNA in the region of ITS1/5.8S/ITS2 is a substrate for RNase P in vitro, nuclear RNase P was partially purified to remove contaminating nucleases. Cleavage assays were performed using an rRNA substrate transcribed in vitro which includes the 5.8S region and its surrounding processing sites in ITS1 and ITS2. Discrete cleavages of this rRNA substrate were coincident with the peak fractions of nuclear RNase P, but not with fractions corresponding to mitochondrial RNase P or ribonuclease MRP RNA. The cleavage activity is sensitive to treatment with micrococcal nuclease, also consistent with an activity attributable to RNase R The strong RNase P cleavage sites were mapped and their possible relationships to steps in the rRNA processing pathway are considered. These observations suggest an intimate relationship between the processes of tRNA and rRNA maturation in the eukaryotic nucleus.
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PMID:An RNase P RNA subunit mutation affects ribosomal RNA processing. 877 95

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