Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

A second major species of leucine tRNA, tRNA Leu UAG (formerly designated tRNA Leu CUA) was purified from baker's yeast in a three-step procedure entailing BD-cellulose chromatography in the presence and absence of Mg2+ and Sephadex G-100 gel filtration. Results of aminoacylation and partial RNase T1 digestion experiments showed that this tRNA retains a native conformation under conditions that denature yeast tRNA Leu m5CAA (tRNA3 Leu). The primary structure of baker's yeast tRNA Leu UAG was elucidated by application of sensitive radioactive isotope derivative ("postlabeling") methods. Complete RNase T1 and A and partial RNase U2 fragments, prepared from non-radioactive tRNA and 5'-half and 3'-half molecules, were separated by two-dimensional polyethyleneimine-cellulose anion-exchange thin-layer chromatography and isolated by a novel micropreparative procedure affording high yields of these compounds in sufficient purity for subsequent tritium derivative analysis. Base composition and sequence of oligonucleotides were analyzed by tritium derivative methods. Molar ratios of the fragments were determined from the radioactivity of 3H-labeled nucleoside trialcohols in combination with base analysis. 2'-O-Methylated guanosine was characterized using the [gamma-32P]ATP/polynucleotide kinase reaction. The analysis of classical complete and partial RNase digests by the tritium derivative methods yielded the complete nucleotide sequence of the tRNA. A total of about 20 A260 units of the RNA was used for analysis, i.e. considerably less material than required for conventional spectrophotometric analysis. A different sequencing approach, consisting of a combination of "readout sequencing" with tritium sequencing of complete RNase T1 and A fragments, was applied to the 3'-half molecule. The 3'-half molecule was labeled with 32P at its 5' terminus, partially degraded with RNase T1, U2, and Phy1 and with alkali, and subjected to polyacrylamide gel electrophoresis. The sequence was read off the gel on the basis of cleavage patterns and size of the fragments. While the readout procedure provided only the positions of A, U, C, and G residues in the chain, additional information from tritium derivative analysis was utilized to define the positions of the modified nucleosides. The readout sequencing procedure was found to require less than 0.01 A260 unit of RNA and the analysis of the complete fragments about 6 A260 units. Interesting structural features of tRNA Leu UAG are (a) the location of unique, leucine tRNA iso-acceptor-specific sequences next to U-8, a constant nucleotide participating in synthetase recognition, (b) the occurrence of 1-methyladenosine in the T loop, a modification not present in the structurally related tRNA Leu m5CAA, and (c) the unusual presence of an unmodified uridine in the first position of the anticodon, which may be related to the unusual coding properties reported for this tRNA.
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PMID:Yeast tRNA Leu UAG. Purification, properties and determination of the nucleotide sequence by radioactive derivative methods. 37 75

The interaction of ribonuclease T1 with tetraprotonated spermine (SPM4+), Mg2+, phosphate and other ionic ligands at pH 6.0 was investigated in binding experiments at 25 degrees C and/or by their effects on the midpoint temperature for thermal unfolding of the enzyme. SPM4+ binding with the native protein at 25 degrees C was characterized by an association constant of approximately 2 x 10(4) M-1. This ligand also binds to the unfolded protein but with a approximately 35-fold lower affinity. Phosphate binds at the active site whereas Mg2+ and SPM4+ cations compete for binding at a polyanionic locus that probably involves residues Glu-28, Asp-29, and Glu-31 at the C-terminal end of the alpha-helix. Steady-state kinetic studies using minimal RNA substrates demonstrated that SPM4+ binding with the enzyme does not affect its catalytic activity. SPM4+ also preferentially binds with the folded form of the disulfide-reduced enzyme which has the same or slightly enhanced catalytic properties compared with native ribonuclease T1. The unfolding rate for the native protein in 8 M urea was approximately 8-fold lower in the presence of 0.05 M SPM4+. SPM4+ appears to increase the amplitude of an unobserved fast phase(s) for refolding of the native enzyme. A single kinetic phase characterized refolding of the reduced enzyme which was slightly faster than the slowest refolding phase for the native form.
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PMID:Spermine stabilization of folded ribonuclease T1. 197 May 67

Three overlapping RNA fragments containing the pseudoknot, as found in the tRNA-like structure of turnip yellow mosaic virus (TYMV) RNA, have been isolated and purified. Site-directed cleavage of TYMV RNA by RNase H, followed by ammonium sulphate precipitation and ion-exchange HPLC, yielded a pure preparation of a 3'-terminal, 112-nucleotide TYMV RNA fragment. Transcription of TYMV cDNA by T7 RNA polymerase, resulted in the isolation of an 88-nucleotide fragment. Finally, a 44-nucleotide fragment containing the TYMV RNA pseudoknot and strongly resembling the aminoacyl acceptor arm of the viral RNA was also synthesised using T7 RNA polymerase. The three fragments were isolated in milligram amounts and used for biochemical structure mapping, ultraviolet melting studies and NMR spectroscopy. Chemical modification with diethyl pyrocarbonate and sodium bisulphite and enzymatic digestion with RNase T1 confirmed the presence of the pseudoknot in the 44-nucleotide fragment. Also the analogue of the T-stem and T-loop of the tRNA-like structure of TYMV RNA was found. The results of modification at various temperatures in Mg2+-containing buffers were in general agreement with optical melting studies. Ultraviolet melting analysis of the longer fragments revealed their greater complexity and the results appear similar to those obtained for some tRNA species. To obtain direct biophysical evidence for base-pairing and stacking interactions in the pseudoknot, NMR studies were initiated. The first proton-NMR spectra ever obtained for plant viral RNA fragments are presented. NMR spectra were recorded at various buffer conditions and at various temperatures. The spectra for the 112-nucleotide and 88-nucleotide fragment are too complicated to be solved at present. In the case of the 44-nucleotide fragment, however, the imino proton resonances are well separated and this system turns out to be most promising for structural studies.
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PMID:Biochemical and biophysical analysis of pseudoknot-containing RNA fragments. Melting studies and NMR spectroscopy. 277 53

The accessibility of nucleotides in Escherichia coli tRNAfMet to chemical and enzymatic probes in the presence and absence of methionyl-tRNA synthetase has been investigated. Dimethyl sulfate was used to probe the reactivity of cytosine and guanosine residues. The N-3 position of the wobble anticodon base, C34, was strongly protected from methylation in the tRNA-synthetase complex. A synthetase-induced conformational change in the anticodon loop was suggested by the enhanced reactivity of C32 in the presence of enzyme. Cytosine residues in the dihydrouridine loop and in the 3'-terminal CCA sequence showed little or no change in reactivity. Methylation of the N-7 position of guanosine residues G42, G52, and G70 was partially inhibited by the synthetase. Nuclease digestion of tRNAfMet with alpha-sarcin in the presence of 1-2 mM Mg2+ resulted in cleavage mainly at C71 in the acceptor stem and was strongly inhibited by synthetase. Other nuclease digestion experiments using the single strand specific nucleases RNase A and RNase T1 revealed weak protection of nucleotides in the D loop and strong protection of nucleotides in the anticodon on complex formation. The present data, together with previous structure-function studies on this system, indicate strong binding of methionyl-tRNA synthetase to the anticodon of tRNAfMet, leading to a change in the conformation of the anticodon loop and stem. We propose that this, in turn, produces more distant, and possibly relatively subtle, conformational changes in other parts of the tRNA structure that ultimately lead to proper orientation of the 3' terminus of the tRNA with respect to the active site of the enzyme.
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PMID:Study of the interaction of Escherichia coli methionyl-tRNA synthetase with tRNAfMet using chemical and enzymatic probes. 309 57

A "common-arm" fragment from wheat germ (Triticum aestivum) 5S RNA has been produced by enzymatic cleavage with RNase T1 and sequenced via autoradiography of electrophoresis gels for the end-labeled fragments obtained by further RNase T1 partial digestion. The existence, base pair composition, and base pair sequence of the common arm are demonstrated for the first time by means of proton 500-MHz nuclear magnetic resonance. From Mg2+ titration, temperature variation, ring current calculations, sequence comparisons, and proton homonuclear Overhauser enhancement experiments, additional base pairs in the common arm of the eukaryotic 5S RNA secondary structure are detected. Two base pairs, G41 X C34 and A42 X U33 in the hairpin loop, could account for the lack of binding between the conserved GAAC segment of 5S RNA and the conserved Watson-Crick-complementary GT psi C segment of tRNAs.
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PMID:500-MHz proton homonuclear Overhauser evidence for additional base pair in the common arm of eukaryotic ribosomal 5S RNA: wheat germ. 310 68

The stability of the folded conformation of ribonuclease T1 is increased by 0.8, 1.8, and 3.3 kcal/mol in the presence of 0.1 M NaCl, MgCl2, and Na2HPO4, respectively. This remarkable increase in the conformational stability results primarily from the preferential binding to the native protein of one Mg2+ or two Na+ ions at cation-binding sites and by the binding of one HPO4(2-) ion at an anion-binding site. Only modest binding constants, 6.2 (Na+), 155 (Mg2+), and 282 M-1 (HPO4(2-)), are required to account for the enhanced stability. One important goal of the modification of proteins through genetic engineering is to increase their stability. Our results suggest that the creation of specific cation- and anion-binding sites on the surface of a protein through amino acid substitutions might be a generally useful way of achieving this goal. The design of these sites will be aided by the recent availability of detailed structural information on cation- and anion-binding sites.
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PMID:Ribonuclease T1 is stabilized by cation and anion binding. 313 46

The low temperature structural transition (low leads to high) of 5 S RNA from Escherichia coli is investigated by partial digestion with ribonuclease T1. In addition to a general masking of guanines from the nuclease, differential changes of accessibility are observed when Mg2+ and salt concentrations are increased to bring about the low leads to high transition. Residue G13 becomes more exposed in the high form while residues G54, G56, G61, G72, and G83-86 become less exposed. The observed cutting rate at other sites is unchanged. A possible conformational change is discussed which could explain the observed changes in RNase T1 digestion patterns as well as the physical chemical observations.
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PMID:A characterization of the low temperature structural transition of Escherichia coli 5 S RNA by partial enzymatic digestion. 619 17

We analyzed the genetic structure and gene products of the newly isolated avian sarcoma virus UR1, which recently has been shown to be replication defective and to contain no sequences homologous to the src gene of Rous sarcoma virus. The sizes of the genomic RNAs of UR1 and its associated helper virus, UR1AV, were determined to be 29S and 35S (5.9 and 8.5 kilobases), respectively, by gel electrophoresis and sucrose gradient sedimentation. RNase T1 oligonucleotide mapping of purified viral RNAs indicated that UR1 RNA contains eight unique oligonucleotides in the middle of the genome and shares four 5'-terminal and three 3'-terminal oligonucleotides with UR1AV RNA. The unique sequences of UR1 and Fujinami sarcoma virus were found to be closely related to each other by molecular hybridization of UR1 RNA with DNA complementary to the unique sequence of Fujinami sarcoma virus RNA, but minor differences were found by oligonucleotides fingerprinting. In the regions flanking the unique sequences, UR1 and Fujinami sarcoma viral RNAs contain distinct oligonucleotides, which are shared with oligonucleotides of the respective helper viral RNAs. Cell transformed with UR1 produce a single 29S RNA species which contains a UR1 unique sequence; this species is most likely the mRNA coding for the transforming protein. In UR1-transformed cells, a phosphoprotein fo 150,000 daltons (p150) was detected by immunoprecipitation with antiserum against gag proteins. p150 was associated with a protein kinase activity that was capable of phosphorylating p150 itself, immunoglobulin G of antiserum, and a soluble substrate, alpha-casein. This enzyme transferred phosphate exclusively to tyrosine residues of substrates in vitro, but p 150 labeled in vivo with 32P contained both phosphoserine and phosphotyrosine. The in vitro kinase reaction was not affected by the presence of cyclic AMP or cyclic GMP and strongly preferred Mn2+ over Mg2+. Thus, the properties of UR1 protein are almost identical to those of Fujinami sarcoma virus protein.
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PMID:Genetic structure, transforming sequence, and gene product of avian sarcoma virus UR1. 627 Mar 78

A nickel complex has been shown to promote conformation-specific oxidation of guanosine in polynucleotide RNA. In all cases, reaction was strictly dependent on the solvent exposure and surface properties of guanine N7. Modification of native tRNA(Phe) (yeast) was detected at G18, G19, G20, and Gm34 and concurred with predictions based on its crystal structure. Additional guanine derivatives became exposed to oxidation only after the tRNA unfolded in the absence of Mg2+. Reaction of the Tetrahymena group I intron RNA (L-21 ScaI) also compared favorably to its three-dimensional model by appropriately identifying guanosine residues in hairpin loops, duplex termini, and the essential cofactor binding site. These results complemented prior data generated by hydroxyl radical, and in combination they served to distinguish the solvent accessibility of sugar backbone and base positions in guanosine residues. Most importantly, this nickel complex exhibited greater selectivity than either dimethyl sulfate or RNase T1 for characterizing tRNA(Phe) and intron RNA.
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PMID:A highly sensitive probe for guanine N7 in folded structures of RNA: application to tRNA(Phe) and Tetrahymena group I intron. 834 71

To elucidate the metabolic function of mRNA polyadenylation in Escherichia coli. we searched for a polyadenylate-binding protein as a potential mediator of the function of the poly(A) moiety. Using a nitrocellulose filter-binding assay and a Northwestern blot technique, a protein in the ribosomal supernatant fraction of E coli was identified and purified to homogeneity. N-terminal sequence analysis yielded a 25-residue sequence which corresponded to the 25 N-terminal amino acids of protein S1, one of the proteins of the E coli 30S ribosomal subunit. Poly(A) binding to S1 protein was inhibited by Mg2+ and Mn2+ and by ATP and stimulated 8-fold by 100 mM KCl. The binding of S1 to poly(A) occurred with an association constant of 3 x 10(6) M-1 and seemed to be only mildly cooperative. Competition studies of the binding of poly(A) and poly(C) to purified S1 protein were consistent with the presence of two polynucleotide binding sites, of which one binds poly(A) five times more strongly than poly(C), whereas the other binds poly(C) 50 times more strongly than poly(A). Poly(A) bound to 30S ribosomal subunits but not to 50S ribosomes. To study possible association of S1 with the poly(A) tracts of E coli mRNA in the process of translation, poly(A) RNA was isolated from polysomes by oligo(dT) cellulose chromatography and the poly(A) RNA with bound protein was eluted either directly or after digestion with RNase T1 and A. When subjected to Western blot analysis with antibody to S1, both poly(A) RNA and isolated poly(A) tracts revealed bound S1 protein. The implications of these results for the possible interaction of poly(A) tracts of mRNA and the translational machinery of E coli are discussed.
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PMID:Identification of ribosomal protein S1 as a poly(A) binding protein in Escherichia coli. 945 50


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