EC:3.1.27.3 - FACTA Search

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Query: EC:3.1.27.3 (RNase T1)
1,228 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Four purified tRNALys species from 13-day-old chick embryo muscle have been characterized with respect to the following properties: qualitative oligoribonucleotide composition (polyacrylamide gel electrophoresis after RNase T1 digestion), anticodon response towards AAG and AAA (equilibrium dialysis and polylysine synthesis), strength of the aminoacyl bond (de-esterification kinetics), sedimentation coefficient, and temperature-dependent double helix-to-coil transition. The results confirm the existence of four molecularly independent lysine-specific tRNA's in this eukaryotic system.
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PMID:Comparative characterization of four purified lysine-specific transfer ribonucleic acids from chicken embryos. 40 37

Incubation of isolated rat liver mitochondria with radioactive amino acids resulted in the charging of tRNAs for arginine, asparagine, leucine, lysine, methionine, proline and valine. The aminoacyl-tRNAs were shown to be distinct from their cytosolic counterparts by chromatography on RPC-5. By electrophoresis on urea polyacrylamide slab gels it was found that all these mitochondrial aminoacyl-tRNAs were about 70-76 nucleotides long. The unique mitochondrial asparaginyl- and prolyl-tRNAs, not previously identified in mammalian cells, were shown to hybridize to mtDNA. Mitochondrial leucyl-tRNA separated into 3 peaks on RPC-5 and the first species was shown to be different than a combination of the other two by molecular size and partial RNase T1 digestion patterns. Each was coded by a separate gene on mtDNA as shown by partial additivity of hybridization. Separate genes for mitochondrial tRNAMetm and tRNAMetf, separated by RPC-5 chromatography, were also demonstrated. These results bring to 21 the number of individual tRNAs coded by mammalian mtDNA.
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PMID:Mammalian mitochondrial transfer RNAs: chromatographic properties, size and origin. 42 2

Cytoplasmic initiator transfer ribonucleic acid (tRNAinit) was purified from bulk Torulopsis (Candida) utilis tRNA by a series of column chromatography procedures. Sequence analysis of the products of complete and partial digestion of this tRNA with ribonuclease A [EC 3.1.4.22] and ribonuclease T1 [EC 3.1.4.8] enabled us to determine the complete primary structure of the molecule. The chain length of this tRNA was 76, including 11 modified nucleotides. The structure of the tRNA was arranged into a cloverleaf model and compared with those of other initiator tRNA species. As in the cytoplasmic initiator tRNA's of most other eukaryotic cells, the sequence -A-U-C-G- is contained in this tRNA in place of the usual -T-psi-C-G (or A)- found in other tRNA's.
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PMID:The primary structure of cytoplasmic initiator transfer ribonucleic acid from Torulopsis utilis. 57 64

1. The nucleotide chain of tRNA Cys from baker's yeast was readily split at the anticolon into two large fragments by brief treatment with ribonuclease T1.2. The whole molecule and the two derived large fragments were completely digested with (a) pancreatic ribonuclease and (b) ribonuclease T1. The fragments present in each of the digests were separated and sequenced by conventional methods. 3. The groups of fragments derived from the two methods of digestion were entirely compatible with each other. 4. The molecule is 75 nucleotides long, but, as isolated, lacks the terminal adenosine and the neighboring cytidylic acid residue. The minor nucleotides 1-methyladenylic acid, 7-methylguanylic acid, 5-methylcytidylic acid and N6 (gamma gamma-dimethylallyl)adenylic acid (isopentenyladenylic acid) were identified.
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PMID:The nucleotide sequence of cysteine transfer ribonucleic acid from baker's yeast. Products of complete digestion with pancreatic ribonuclease and ribonuclease T1. 81 5

The methionine acceptor activity of a crude tRNA from bakers' yeast was resolved into two peaks (I and II) by column chromatography on DEAE-Sephadex A-25 with a 1 M phosphate system. Methionine tRNA from peak II was not formylated by E. coli methionyl-tRNA transformylase [EC 2.1.2.9.] after being charged with methionine, whereas that from peak I was formylatable under the same conditions. A substantial amount of unlabelled methionine tRNA, tRNAMetm, was highly purified from the peak II fraction by successive chromatographic procedures. The purified tRNAMetm was digested with pancreatic ribonuclease A [EC 3.1.4.22] and ribonuclease T1 [EC 3.1.4.8]. The digestion products were isolated into individual components and completely sequenced. The results of sequence analysis of the two RNase digests were in good agreement and indicated that the chain length of this tRNA is 76, including 13 modified nucleotides. These oligonucleotide fragments can be constructed into a unique total sequence, assuming a few conventional features of clover leaf structure for the tRNA was established by analyses of partial digestion products with RNase T1, as reported in the accompanying paper.
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PMID:The primary structure of non-initiator methionine transfer ribonucleic acid from Bakers' yeast. I. Purification and complete digestion with ribonuclease T1 and pancreatic ribonuclease A. 82 24

Large oligonucleotides obtained from partial RNase T1 digestion of tRNAMetm from bakers' yeast (S. cerevisiae, strain Y 185) were isolated by chromatographic procedures and sequenced. The complete sequence of the tRNAMetm was established from the results of this partial digestion, together with those of the complete RNase T1 and A [EC 3.1.4.8 and 22] digestions of tRNAMetm reported in the preceding paper. The structure of this tRNAMetm was arranged into a clover leaf comparable with those of other tRNAMet species including bakers' yeast initiator tRNA.
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PMID:The primary structure of non-initiator methionine transfer ribonucleic acid from Bakers' yeast. II. Partial digestion with ribonuclease T1 and derivation of the complete sequence. 82 25

A double-labeling procedure for sequence analysis of nonradioactive polyribonucleotides is detailed, which is based on controlled endonucleolytic degradation of 3'-terminally (3H)-labeled oligonucleotide-(3') dialcohols and 5"-terminal analysis of the partial (3H)-labeled fragments following their separation according to chain length by polyethyleneimine- (PEI-)cellulose TLC and detection by fluorography. Undesired nonradioactive partial digestion products are eliminated by periodate oxidation. The 5'-termini are assayed by enzymic incorporation of (32p)-label into the isolated fragments, enzymic release of (32p)-labeled nucleoside-(5') monophosphates, two-dimensional PEI-cellulose chromatography, and autoradiography. Using this procedure, as little as 0.1 - 0.3 A260 unit of tRNA is needed to sequence all fragments in complete ribonuclease T1 and A digests, whereas radioactive derivative methods previously described by us1-4 required 4 - 6 A260 units.
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PMID:A double-labeling procedure for sequence analysis of picomole amounts of nonradioactive RNA fragments. 82 84

Studies were conducted on the stimulatory effect that various nucleic-acid-binding compounds have on the hydrolysis of RNA and polyribonucleotides by pancreatic ribonuclease A and by other ribonucleases. The stimulatory activity of chloroquine on tRNA hydrolysis by pancreatic ribonuclease was due to the formation of oligonucleotides of a wide range of sizes and was not due to the formation of very short ( n greater than 5) oligonucleotide fragments of tRNA. The dextrorotatory and levorotatory isomers of chloroquine did not differ in their ability to stimulate the hydrolysis of tRNA by pancreatic ribonuclease A. In addition to chloroquine and primaquine, other nucleic-acid-binding compounds (e.g., quinacrine, lucanthone, and proflavin) stimulated the hydrolysis of tRNA by pancreatic ribonuclease A. Chloroquine did not alter the rate of hydrolysis by pancreatic ribonuclease A of low-molecular-weight substrates (cytidine cyclic 2':o'-monophosphate, uridine cyclic 2':3'-monophosphate, cytidylyl-adenosine, or uridylyl-uridine). Furthermore, chloroquine and primaquine did not affect the hydrolysis of poly(A) by high concentrations of pancreatic ribonuclease A. In studies on the hydrolysis of tRNA by other endoribonucleases, several of the nucleic-acid-binding compounds (e.g., quinacrine and ethidium) exhibited appreciable inhibition of both ribonuclease N1 and ribonuclease T1. None of the compounds tested stimulated the activity of ribonuclease T1, and only chloroquine, and perhaps lucanthone, stimulated the hydrolysis of tRNA by ribonuclease N1.
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PMID:Effect of nucleic-acid-binding compounds on the hydrolytic activity of various ribonucleases. 120 47

The Saccharomyces cerevisiae transcription factors (TF) IIIB and IIIC assemble onto their respective DNA-binding sites on the SUP4 tRNA(Tyr) gene at 0 degrees C. RNA polymerase III specifically associates at 0 degrees C with this TFIIIC-TFIIIB-DNA complex to form a stable "closed" promoter complex in which the DNA surrounding the transcriptional start retains its duplex form. Promoter "opening" is a temperature-dependent and readily reversible process that involves up to 22 unwound base-pairs of DNA, and can be followed by analyzing the hyperreactivity of thymine to KMnO4 oxidation. This promoter opening increases progressively from 10 degrees C to 40 degrees C, with at least two regions within the transcription bubble appearing to melt independently. In contrast, the temperature dependence of forming an initiated transcription complex containing a 17 nucleotide nascent RNA chain displays a sharp transition between 10 degrees C and 15 degrees C. When RNA polymerase initiates transcription under conditions that limit the nascent RNA chain to less than six nucleotides, there is no displacement of the transcription bubble. These transcription complexes are distinguishable from "open" promoter complexes in their maintenance of the transcription bubble at 0 degrees C, and from transcription complexes with more extended (17 nucleotide) RNA chains in their sensitivity to disruption by heparin. In light of recent results by others that demonstrate a requirement for an RNA transcription factor in a Bombyx mori-based in vitro RNA polymerase III transcription system, we have searched for a comparable component in the S. cerevisiae-derived system. We show that if an RNA component is required in the yeast-derived system, it is not susceptible to inactivation by massive amounts of micrococcal nuclease, RNase A, or RNase T1.
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PMID:Formation of open and elongating transcription complexes by RNA polymerase III. 161 62

Messenger RNA molecules 30-35 bases long, with sequences related to the 5'-region of cro-mRNA from lambda-phage, were prepared by T7 transcription from synthetic DNA templates. Each mRNA contained five or six internal uridine residues, which were transcribed using a mixture of UTP and thio-UTP. Initiation complexes were formed with Escherichia coli 30S ribosomes in the presence or absence of tRNA(fMet), and cross-linking of the thio-U residues was induced by UV irradiation at wavelengths greater than 300 nm. The cross-linked ribosomal proteins were identified immunologically, and cross-linked regions of the 16S RNA were isolated by excision with ribonuclease H and suitable deoxyoligonucleotides. In both cases, the particular thio-U residue involved in the cross-link was identified by ribonuclease T1 fingerprinting of the (radioactive) mRNA in the isolated cross-linked complex. The principal results were that, at thio-U positions upstream of the AUG codon, specific cross-linking occurred to protein S7 and to the 3'-terminus of the 16S RNA, in agreement with similar experiments using 70S ribosomes. Less specific cross-linking was observed to proteins S1, S18 and S21 at various positions within the mRNA. Six bases downstream from the AUG codon, a tRNA-dependent cross-link was found to position approximately 1050 of the 16S RNA, but--in contrast to similar experiments with 70S ribosomes--no cross-linking was found to the 1390-1400 region.
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PMID:The location of mRNA in the ribosomal 30S initiation complex; site-directed cross-linking of mRNA analogues carrying several photo-reactive labels simultaneously on either side of the AUG start codon. 165 Dec 32

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