Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Incubation of CMP in 2H2O with 0.5M cysteine methyl ester at p2H 5 and 37 degrees C for 24 h resulted in 43% exchange of 5-H to 5-2H. No deamination of the cytosine nucleus was noted during this treatment. Native and denatured DNA samples from calf thymus were treated in 3H2O with cysteine methyl ester at pH 5 and 37 degrees C for 24 h and incorporation of tritium into each DNA base was determined by enzymic digestion of the treated DNA. The order of the specific radioactivity found was cytosine greater than guanine greater than adenine greater than thymine for denatured DNA and guanine greater than adenine approximately cytosine greater than thymine for native DNA. The ratio of radioactivity for denatured/native was 11.6 for cytosine, 1.5 for guanine, 1.8 for adenine and 1.1 for thymine. Hence the incorporation in cytosine under the reaction conditions is preferential for single-stranded, nonhelical regions of DNA. Escherichia coli glutamic acid tRNA II was treated in 3H2O with 1.24 M cysteine methyl ester at pH 5 and 37 degrees C. The 24-h-treated tRNA was digested with ribonuclease T1 and the fragments were fractionated. Each fragment was then digested with ribonuclease T2 into mononucleotides and the radioactivity distribution among the bases was determined. The average radioactivity found for each of the bases of the four major nucleotides was cytosine greater than guanine approximately adenine greater than uracil. The radioactivity in cytosine varied greatly among the RNase T1 fragments, the ratio of the highest to the lowest radioactivity being 18.7. The corresponding value for guanine was 11.1, for adenine 4.73 and for uracil 3.64. Based on the data obtained, it was deduced that in this tRNA the anticodon loop, the dihydrouridine loop and the extra loop were "exposed" under the conditions employed for the labeling. The 5'-terminal cytosine of the anticodon loop was in a "non-exposed" state, a situation similar to that previously reported for E. coli tyrosine tRNA [Cashmore, A. R., Brown, D. M. & Smith, J. D. (1971) J. Mol. Biol. 59, 359-373] and for E. coli formylmethionine tRNA [Goddard J. P.+Schulman L. H. (1972) J. Biol. Chem. 247, 3864-3867]. Both cytosine 48, located at the 3'-terminal of the extra loop, and guanine 15 in the dihydrouridine loop were in an "emposed" state. This finding does not agree with a tRNA model in which this pair of cytosine and guanine, commonly found in tRNA sequences, forms hydrogen bondings. Positions 30--32, 61--64 and 71, which are located in the stems, were found to be strongly "buried".
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PMID:Conformation of Escherichia coli glutamic acid tRNA II as studied by hydrogen-tritium exchange catalyzed by cysteine methyl ester. 0 69

Dinucleoside diphosphates of the general type pGpN have been prepared enzymatically using ribonuclease N1. Alkylated uridines or cytidines, which are products of carcinogens acting on nucleic acids, were tested in dinucleoside diphosphates for their ability to stimulate the binding of Ala- or Val-tRNA to ribosomes. O2-Ethyl C and 3-methyl C functioned as U, but not as C. In contrast, 3-methyl U behaved as C, but not as U. Both O2 and O4-ethyl U could be recognized as C or U, although binding in both cases was weak. Thus, modifications of the hydrogen-bonding sites of U or C causes miscoding and could be considered to represent mutagenic reactions.
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PMID:Synthesis and coding properties of dinucleoside diphosphates containing alky pyrimidines which are formed by the action of carcinogens on nucleic acids. 15 50

The reaction of Torulopsis (Candida) utilis 5S ribosomal RNA with kethoxal (beta-ethoxy-alpha-ketobutyraldehyde) was studied in an attempt to identify the exposed guanine residues. At most 7-8 out of 32 guanine residues in T.utilis 5S RNA were kethoxalated after reaction at 37 degrees C for 4 h in the presence of magnesium ions. Localization of the kethoxalated guanine residues in T.utilis 5S RNA was achieved by sequence analyses of RNase T1 digests of the kethoxalated 5S RNA. These analyses showed that residues G37, G57, G91, and some of the three guanine residues G80, G82, and G85, are the most accessible sites. Residues G30, G41, and G49 also reacted with kethoxal though less strongly. These results are for the most part compatible with our secondary structure model for T.utilis 5S 5S RNA (Nishikawa and Takemura (1974) J. Biochem. 76, 935-947). However, partial formation of some hydrogen bonds within the loop region of the model seems to be necessary to explain the inaccessibility of residue G101 to kethoxal. The results are also discussed in comparison with those of similar studies on E.coli 5S RNA.
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PMID:Structure and function of 5S ribosomal ribonucleic acid from Torulopsis utilis. IV. Detection of exposed guanine residues by chemical modification with kethoxal. 56 34

The 42S RNA from Semliki Forest virus contains a polyadenylate [poly(A)] sequence that is 80 to 90 residues long and is the 3'-terminus of the virion RNA. A poly(A) sequence of the same length was found in the plus strand of the replicative forms (RFs) and replicative intermediates (RIs) isolated 2 h after infection. In addition, both RFs and RIs contained a polyuridylate [poly(U)] sequence. No poly(U) was found in virion RNA, and thus the poly(U) sequence is in minus-strand RNA. The poly(U) from RFs was on the average 60 residues long, whereas that isolated from the RIs was 80 residues long. Poly(U) sequences isolated from RFs and RIs by digestion with RNase T1 contained 5'-phosphorylated pUp and ppUp residues, indicating that the poly(U) sequence was the 5'-terminus of the minus-strand RNA. The poly(U) sequence in RFs or RIs was free to bind to poly(A)-Sepharose only after denaturation of the RNAs, indicating that the poly(U) was hydrogen bonded to the poly(A) at the 3'-terminus of the plus-strand RNA in these molecules. When treated with 0.02 mug of RNase A per ml, both RFs and RIs yielded the same distribution of the three cores, RFI, RFII, and RFIII. The minus-strand RNA of both RFI and RFIII contained a poly(U) sequence. That from RFII did not. It is known that RFI is the double-stranded form of the 42S plus-strand RNA and that RFIII is the experimetnally derived double-stranded form of 26S mRNA. The poly(A) sequences in each are most likely transcribed directly from the poly(U) at the 5'-end of the 42S minus-strand RNA. The 26S mRNA thus represents the nucleotide sequence in that one-third of the 42S plus-strand RNA that includes its 3'-terminus.
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PMID:Replication of semliki forest virus: polyadenylate in plus-strand RNA and polyuridylate in minus-strand RNA. 97 99

Poly(8-bromoadenylic acid) (poly(8-BrA)) has been synthesized by polymerization of 8-BrADP with polynucleotide phosphorylase in the presence of oligonucleotide primers. In the absence of oligonucleotides, significant (i.e. more than 1%) polymerization does not occur. Oligo(I) primer was removed selectively from the polymer with ribonuclease T1 to yield the homopolymer, poly(8-BrA). End group analysis, based on quantitative infrared measurement of the (Ip)3I-primed polymer, indicates an average degree of polymerization of about 70 residues. The primed polymers and the homopolymer appear to have similar helical structures, probably double-stranded with mutual hydrogen bonding interaction of BrA residues. Preliminary NMR observations of poly(8-BrA) with a tetrainosinic acid primer at the 5' ends of the polymer chain ((Ip)3I-(8-BrA)n) are consistent with the existence of a rigid helical structure below the melting range of the primed polymer. Above the melting range (81 degrees) the H1' coupling constants of (Ip)3I-(8-BrA)n and of polyadenylic acid (poly(A)) suggest a significantly higher population of C3' endo conformation of ribose residues in the primed polymer than in poly(A) at 81 degrees.
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PMID:Poly(8-bromoadenylic acid): synthesis and characterization of an all-syn polynucleotide. 112 40

The crystal structure of a mutant ribonuclease T1 (Y45W) complexed with a non-cognizable ribonucleotide, 2'AMP, has been determined and refined to an R-factor of 0.159 using X-ray diffraction data at 1.7 A resolution. A specific complex of the enzyme with 2'GMP was also determined and refined to an R-factor of 0.173 at 1.9 A resolution. The adenine base of 2'AMP was found at a base-binding site that is far apart from the guanine recognition site, where the guanine base of 2'GMP binds. The binding of the adenine base is mediated by a single hydrogen bond and stacking interaction of the base with the imidazole ring of His92. The mode of stacking of the adenine base with His92 is similar to the stacking of the guanine base observed in complexes of ribonuclease T1 with guanylyl-2',5'-guanosine, reported by Koepke et al., and two guanosine bases, reported by Lenz et al., and in the complex of barnase with d(GpC), reported by Baudet & Janin. These observations suggest that the site is non-specific for base binding. The phosphate group of 2'AMP is tightly locked at the catalytic site with seven hydrogen bonds to the enzyme in a similar manner to that of 2'GMP. In addition, two hydrogen bonds are formed between the sugar moiety of 2'AMP and the enzyme. The 2'AMP molecule adopts the anti conformation of the glycosidic bond and C-3'-exo sugar pucker, whereas 2'GMP is in the syn conformation with C-3'-endo-C'-2'-exo pucker. The mutation enhances the binding of 2'GMP with conformational changes of the sugar ring and displacement of the phosphate group towards the interior of the catalytic site from the corresponding position in the wild-type enzyme complex. Comparison of two crystal structures obtained provides a solution to the problem that non-cognizable nucleotides exhibit unexpectedly strong binding to the enzyme, compared with high specificity in nucleolytic activity. The results indicate that the discrimination of the guanine base from the other nucleotide bases at the guanine recognition site is more effective than that estimated from nucleotide-binding experiments so far.
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PMID:Three-dimensional structure of a mutant ribonuclease T1 (Y45W) complexed with non-cognizable ribonucleotide, 2'AMP, and its comparison with a specific complex with 2'GMP. 131 85

In the genetically mutated ribonuclease T1 His92Ala (RNase T1 His92Ala), deletion of the active site His92 imidazole leads to an inactive enzyme. Attempts to crystallize RNase T1 His92Ala under conditions used for wild-type enzyme failed, and a modified protocol produced two crystal forms, one obtained with polyethylene glycol (PEG), and the other with phosphate as precipitants. Space groups are identical to wild-type RNase T1, P2(1)2(1)2(1), but unit cell dimensions differ significantly, associated with different molecular packings in the crystals; they are a = 31.04 A, b = 62.31 A, c = 43.70 A for PEG-derived crystals and a = 32.76 A, b = 55.13 A, c = 43.29 A for phosphate-derived crystals, compared to a = 48.73 A, b = 46.39 A, c = 41.10 A for uncomplexed wild-type RNase T1. The crystal structures were solved by molecular replacement and refined by stereochemically restrained least-squares methods based on Fo greater than or equal to sigma (Fo) of 3712 reflections in the resolution range 10 to 2.2 A (R = 15.8%) for the PEG-derived crystal and based on Fo greater than or equal to sigma (Fo) of 6258 reflections in the resolution range 10 to 1.8 A (R = 14.8%) for the phosphate-derived crystal. The His92Ala mutation deletes the hydrogen bond His92N epsilon H ... O Asn99 of wild-type RNase T1, thereby inducing structural flexibility and conformational changes in the loop 91 to 101 which is located at the periphery of the globular enzyme. This loop is stabilized in the wild-type protein by two beta-turns of which only one is retained in the crystals obtained with PEG. In the crystals grown with phosphate as precipitant, both beta-turns are deleted and the segment Gly94-Ala95-Ser96-Gly97 is so disordered that it is not seen at all. In addition, the geometry of the guanine binding site in both mutant studies is different from "empty" wild-type RNase T1 but similar to that found in complexes with guanosine derivatives: the Glu46 side-chain carboxylate hydrogen bonds to Tyr42 O eta; water molecules that are present in the guanine binding site of "empty" wild-type RNase T1 are displaced; the Asn43-Asn44 peptide is flipped such that phi/psi-angles of Asn44 are in alpha L-conformation (that is observed in wild-type enzyme when guanine is bound).(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:His92Ala mutation in ribonuclease T1 induces segmental flexibility. An X-ray study. 131 2

On the basis of molecular dynamics and free-energy perturbation approaches, the Glu46Gln (E46Q) mutation in the guanine-specific ribonuclease T1 (RNase T1) was predicted to render the enzyme specific for adenine. The E46Q mutant was genetically engineered and characterized biochemically and crystallographically by investigating the structures of its two complexes with 2'AMP and 2'GMP. The ribonuclease E46Q mutant is nearly inactive towards dinucleoside phosphate substrates but shows 17% residual activity towards RNA. It binds 2'AMP and 2'GMP equally well with dissociation constants of 49 microM and 37 microM, in contrast to the wild-type enzyme, which strongly discriminates between these two nucleotides, yielding dissociation constants of 36 microM and 0.6 microM. These data suggest that the E46Q mutant binds the nucleotides not to the specific recognition site but to the subsite at His92. This was confirmed by the crystal structures, which also showed that the Gln46 amide is hydrogen bonded to the Phe100 N and O atoms, and tightly anchored in this position. This interaction may either have locked the guanine recognition site so that 2'AMP and 2'GMP are unable to insert, or the contribution to guanine recognition of Glu46 is so important that the E46Q mutant is unable to function in recognition of either guanine and adenine.
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PMID:RNase T1 mutant Glu46Gln binds the inhibitors 2'GMP and 2'AMP at the 3' subsite. 135 Jun 42

Two-dimensional 1H-NMR studies have been performed on ribonuclease F1 (RNase F1), which contains 106 amino acid residues. Sequence-specific resonance assignments were accomplished for the backbone protons of 99 amino acid residues and for most of their side-chain protons. The three-dimensional structures were constructed on the basis of 820 interproton-distance restraints derived from NOE, 64 distance restraints for 32 hydrogen bonds and 33 phi torsion-angle restraints. A total of 40 structures were obtained by distance geometry and simulated-annealing calculations. The average root-mean-square deviation (residues 1-106) between the 40 converged structures and the mean structure obtained by averaging their coordinates was 0.116 +/- 0.018 nm for the backbone atoms and 0.182 +/- 0.015 nm for all atoms including the hydrogen atoms. RNase F1 was determined to be an alpha/beta-type protein. A well-defined structure constitutes the core region, which consists of a small N-terminal beta-sheet (beta 1, beta 2) and a central five-stranded beta-sheet (beta 3-beta 7) packed on a long helix. The structure of RNase F1 has been compared with that of RNase T1, which was determined by X-ray crystallography. Both belong to the same family of microbial ribonucleases. The polypeptide backbone fold of RNase F1 is basically identical to that of RNase T1. The conformation-dependent chemical shifts of the C alpha protons are well conserved between RNase F1 and RNase T1. The residues implicated in catalysis are all located on the central beta-sheet in a geometry similar to that of RNase T1.
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PMID:The three-dimensional structure of guanine-specific ribonuclease F1 in solution determined by NMR spectroscopy and distance geometry. 151 88

The modes of binding of adenosine 2'-monophosphate (2'-AMP) to the enzyme ribonuclease (RNase) T1 were determined by computer modelling studies. The phosphate moiety of 2'-AMP binds at the primary phosphate binding site. However, adenine can occupy two distinct sites--(1) The primary base binding site where the guanine of 2'-GMP binds and (2) The subsite close to the N1 subsite for the base on the 3'-side of guanine in a guanyl dinucleotide. The minimum energy conformers corresponding to the two modes of binding of 2'-AMP to RNase T1 were found to be of nearly the same energy implying that in solution 2'-AMP binds to the enzyme in both modes. The conformation of the inhibitor and the predicted hydrogen bonding scheme for the RNase T1-2'-AMP complex in the second binding mode (S) agrees well with the reported x-ray crystallographic study. The existence of the first mode of binding explains the experimental observations that RNase T1 catalyses the hydrolysis of phosphodiester bonds adjacent to adenosine at high enzyme concentrations. A comparison of the interactions of 2'-AMP and 2'-GMP with RNase T1 reveals that Glu58 and Asn98 at the phosphate binding site and Glu46 at the base binding site preferentially stabilise the enzyme-2'-GMP complex.
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PMID:Modes of binding of 2'-AMP to RNase T1. A computer modeling study. 152 9


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