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)

The synthesis of cytidine, uridine, guanosine, and adenosine 3'-(S-methyl phosphorothioates) by treatment of the 2',5'-di-O-(4-methoxytetrahydropyran-4-yl)ribonucleosides with 2-(methylthio 4H-1,3,2-benzodioxaphosphorin 2-oxide is described. These nucleotide analogues are stable compounds both in the solid state and the neutral aqueous solution. All four of these compounds are degraded by RNase T2 to the parent nucleotides and methanethiol. In addition, cytidine and uridine 3'-(S-methyl phosphorothioates) are substrates for bovine pancreatic ribonuclease and guanosine 3'-(S-methyl phosphorothioate) is a substrate for RNase T1 and RNase U1. When used in conjunction with a chromophore-producing reagent, nucleoside 3'-(S-methyl phosphorothioates) provide a means for direct kinetic measurement of ribonuclease activity over a wide pH range (pH 2-9). The reactivities of these substrates with ribonucleases are compared to the reactivities of other synthetic substrates as well as a number of natural substrates. The utility of ribonucleoside 3'-(S-methyl phosphorothioates) as substrates for the assay of ribonucleases is discussed.
Biochemistry 1981 Sep 15
PMID:Synthesis of nucleoside 3'-(S-alkyl phosphorothioates) and their use as substrates for nucleases. 627 Nov 88

RNase T1 is folded into an alpha-helix of 4.5 turns, covered by a four-strand antiparallel beta-sheet. Specific recognition of 2'-guanylic acid arises from hydrogen bonding between main chain peptide groups and the O-6 and N-1-H of guanine, as well as from stacking of Tyr 45 on guanine. At the active site, Glu 58, His 92 and Arg 77 are involved in phosphodiester hydrolysis.
Nature 1982 Sep 02
PMID:Specific protein-nucleic acid recognition in ribonuclease T1-2'-guanylic acid complex: an X-ray study. 628 78

SL3-3 is a leukemogenic, ecotropic retrovirus produced by a T-cell line derived from a spontaneous lymphoma of an AKR mouse. We have isolated a molecular clone of its DNA provirus from infected NIH 3T3 fibroblasts. Cloned proviral DNA produced infectious virus upon transfection onto NIH 3T3 cells. Virus derived by transfection induced lymphomas at high frequency in AKR/J, C3H(f)/Bi, CBA/J, and NFS/N mice. Heteroduplex and RNase T1 fingerprinting analyses showed that the genomes of SL3-3 and the non-leukemogenic virus, Akv, contain no major substitutions relative to one another and differ by only a few base changes. These results unambiguously show that SL3-3 is a highly leukemogenic virus and that major rearrangements of the genome relative to Akv are not required for virulence.
J Virol 1982 Sep
PMID:Molecular cloning of a highly leukemogenic, ecotropic retrovirus from an AKR mouse. 629 72

A soluble whole-cell extract prepared accurately from HeLa cells splices 2-3% of the RNA transcribed from a DNA template containing the first and second leader exons of late adenovirus RNA. The spliced RNA was detected by a sensitive technique using hybridization to a single-stranded phage M13 cDNA clone, followed by binding to nitrocellulose filters. The identity of the spliced RNA was established by RNase T1 and pancreatic RNase two-dimensional peptide mapping. The bond formed during the in vitro splicing reaction appears to be a typical 3',5'-phosphodiester bond as judged by its sensitivity to RNase T1. The splicing reaction is specifically inhibited by KCl at concentrations greater than 50 mM and by the addition of cellular RNA. Three features of this system may account for the detection of splicing in a soluble extract: (i) the sensitive and unambiguous hybridization assay, (ii) the high transcriptional activity of the major late promoter of adenovirus, and (iii) the use of the first and second leader exon splice of adenovirus, which may be unusually rapid.
Proc Natl Acad Sci U S A 1983 Sep
PMID:Splicing of adenovirus RNA in a cell-free transcription system. 657 17

Previously we have isolated the specific RNA methyltransferase from the nucleoli of Ehrlich ascites tumor cells. The purified enzyme was found to be specific for methylation of C5 position of cytosine residue in ribosomal RNA in vitro (Obara, 1982b). In the present study, we have investigated the recognition mechanisms of RNA structure by this enzyme from the points of view of both primary and secondary structures. Analysis of in vitro methylation product by ribonuclease T1 digestion indicated the methylation-site(s) was limited to a certain number of nonanucleotide. The next experiments with either Sl nuclease or actinomycin D and ethidium bromide suggested that the enzyme modified only cytidine residue in or located close to the double stranded part of RNA. On the other hand, the characterization of analogues of cytidine residue in the RNA at molecular level showed that the methylation of rRNA was inhibited by either cytidine, CDP or CTP, but little inhibition was observed in the presence of cytosine, 5-methylcytidine and CMP.
J UOEH 1983 Sep 01
PMID:Recognition of the ribosomal RNA structures by purified nucleolar RNA methyltransferase. 667 41

K+-depleted 60S ribosomal subunits from rat liver were submitted to a mild treatment with ribonuclease T1. Ribonucleoprotein fragments could be separated on sucrose gradients only when the digested subunits were partially deproteinized with a high KCl concentration (0.6 M) which removed seven proteins more or less completely and 5S RNA. The RNA and protein content of each fragment has been characterized. The largest ribonucleoprotein enclosed two RNA fragments of about 950,000 and 750,000 daltons and all the salt-resistant proteins except L5. The smallest one enclosed protein L5 (with L11, L17 and L26 in small amounts) and a 67,000 RNA piece. The subsequent hydrolysis of the large ribonucleoprotein produced several other ribonucleoproteins. One of them has been fully characterized: it enclosed a 250,000 RNA fragment and protein L12 (with L11, L25 and L30 in smaller amounts).
Nucleic Acids Res 1981 Sep 11
PMID:Two specific ribonucleoprotein fragments from rat liver 60S ribosomal subunits. 679 92

N-Acetylvalyl-tRNA1Val (AcVal-tRNA1Val) was bound to the P site of uniformly 32P-labeled 70S ribosomes from Escherichia coli and crosslinked to 16S RNA in the 30S ribosomal subunit by irradiation with light of 300-400 nm. To identify the crosslinked nucleotide in 16S RNA. AcVal-tRNA1Val-16S [32P]RNA was digested completely with RNase T1 and the band containing the covalently attached oligonucleotides from tRNA and rRNA was isolated by polyacrylamide gel electrophoresis. The crosslinked oligonucleotide, and the 32P-labeled rRNA moiety released from it by photoreversal of the crosslink at 254 nm, were then analyzed by secondary hydrolysis with pancreatic RNase A and RNase U2. The oligonucleotide derived from 16S RNA was found to be the evolutionarily conserved sequence, U-A-C-A-C-A-C-C-G1401, and the nucleotide crosslinked to tRNA1Val, C1400. The identity of the covalently attached residue in the tRNA was established by using AcVal-tRNA1Val-16S RNA prepared from unlabeled ribosomes. This complex was digested to completion with RNase T1 and the resulting RNA fragments were labeled at the 3' end with [5'-32P]pCp. The crosslinked T1 oligonucleotide isolated from the mixture yielded one major end-labeled component upon photoreversal. Chemical sequence analysis demonstrated that this product was derived from the anticodon-containing pentadecanucleotide of tRNA1Val, C-A-C-C-U-C-C-C-U-cmo5U-A-C-m6A-A-G39(cmo5U, 5-carboxymethoxyuridine). A similar study of the crosslinked oligonucleotide revealed that the residue covalently bound to 16S was cmo5U34, the 5' or wobble base of the anticodon. The adduct is believed to result from formation of a cyclobutane dimer between cmo5U34 of tRNA1Val and C1400 of the 16S RNA.
Proc Natl Acad Sci U S A 1982 Sep
PMID:Covalent crosslinking of tRNA1Val to 16S RNA at the ribosomal P site: identification of crosslinked residues. 681 60

The higher order structure of the functionally important 530 loop in Escherichia coli 16S rRNA was studied in mutants with single base changes at position 517, which significantly impair translational fidelity. The 530 loop has been proposed to interact with the EF-Tu-GTP-aatRNA ternary complex during decoding. The reactivity at G530, U531 and A532 to the chemical probes kethoxal, CMCT and DMS respectively was increased in the mutant 16S rRNA compared with the wild-type, suggesting a more open 530 loop structure in the mutant ribosomes. This was supported by oligonucleotide binding experiments in which probes complementary to positions 520-526 and 527-533, but not control probes, showed increased binding to the 517C mutant 70S ribosomes compared with the non-mutant control. Furthermore, enzymatic digestion of 70S ribosomes with RNase T1, specific for single-stranded RNA, substantially cleaved both wild-type and mutant rRNAs between G524 and C525, two of the nucleotides involved in the 530 loop pseudoknot. This site was also cleaved in the 517C mutant, but not wild-type rRNA, by RNase V1. Such a result is still consistent with a more open 530 loop structure in the mutant ribosomes, since RNase V1 can cut at appropriately stacked single-stranded regions of RNA. Together these data indicate that the 517C mutant rRNA has a rather extensively unfolded 530 loop structure. Less extensive structural changes were found in mutants 517A and 517U, which caused less misreading. A correlation between the structural changes in the 530 loop and impaired translational accuracy is proposed.
Nucleic Acids Res 1995 Sep 11
PMID:Structural changes in the 530 loop of Escherichia coli 16S rRNA in mutants with impaired translational fidelity. 756 70

RNA editing is a process whereby nucleotide insertion, deletion, or base substitution results in the production of an RNA whose sequence differs from that of its template. The mitochondrial RNAs of Physarum polycephalum are processed specifically at multiple sites by both mono- and dinucleotide insertions, as well as apparent cytidine (C) to uridine (U) changes. The precise mechanism and timing of these processing events are currently unknown. We describe here the development of an isolated mitochondrial system in which exogenously supplied nucleotides can be incorporated into RNAs under defined conditions. The results of S1 nuclease protection, nearest neighbor and RNase T1 fingerprint analyses indicate that the vast majority of these newly synthesized mitochondrial RNAs have been accurately and efficiently processed by both mono- and dinucleotide insertions. This work provides a direct demonstration of faithful nucleotide insertion in a mitochondrial editing system. In contrast, the newly synthesized RNAs are not processed by C to U changes in the isolated mitochondria, suggesting that the base changes observed in Physarum are unlikely to occur via a deletion/insertion mechanism.
RNA 1995 Sep
PMID:Accurate and efficient insertional RNA editing in isolated Physarum mitochondria. 758 53

Electrostatic interactions between charged residues and the helix dipole in a protein were investigated by protein engineering methods. In ribonuclease T1, two surface-exposed acidic residues (Glu28 and Asp29) are located near the carboxyl terminus of the alpha-helix between residues 13 and 29. They were replaced, individually and in concert, by the uncharged amides Gln28 and Asn29, and the stabilities of the wild-type protein and its variants were determined as a function of pH. The effects of the two mutations are additive. Either one leads to a marginal destabilization by 0.7 kJ/mol at pH 2 but to a strong stabilization by about 3.2 kJ/mol at pH 7. This suggests that the deprotonations of Glu28 and Asp29 reduce the free energy of stabilization of folded ribonuclease T1 by about 4 kJ/mol each. This destabilization is probably caused by unfavorable electrostatic interactions of Glu28 and Asp29 with the negative end of the helix dipole. The activation energies for the unfolding of the different variants of ribonuclease T1 change in parallel with the differences in the thermodynamic stability when the pH is varied. This indicates that the unfavorable electrostatic interactions of Glu28 and Asp29 are lost very early in unfolding, and are not present in the activated state of unfolding.
J Mol Biol 1995 Sep 08
PMID:Destabilization of a protein helix by electrostatic interactions. 766 25

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