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)

1. 3'-Guanylyl-ethanol, 3'-guanylyl-propanol, and 3'-guanylyl-alpha-glycerol were synthesized by ribonuclease N1 [EC 3.1.4.8] using guanosine 2',3'-cyclic phosphate as a phosphate donor and various alcohols as phosphate acceptors. The yields of these phosphodiesters were 15%, 13.5%, 38.2%, respectively, with respect to phosphate donor under the optimum conditions. No phosphodiester was synthesized when 2-propanol was used as a phosphate acceptor. Thus, primary alcoholic hydroxyl groups may be regarded as the preferred phosphate acceptor. 2. 3'-Guanylyl-glucose and 3'-guanylyl-ribose were synthesized using glucose and ribose as phosphate acceptors. Under the optimum conditions, the yields of guanylyl-glucose amounted to 52.0%, while that of guanylyl-ribose was much lower. The guanylyl-glucose can be regarded as 3'-guanylyl-6-glucopyranose, based on the results of periodate oxidation. 3. Neither hydroxyamino acids (serine and threonine) nor N-acetylserinamide could be phosphorylated under the conditions used for the above phosphorylations. 4. 3'-Guanylyl-glycerol obtained as above was hydrolyzed by snake venon phosphodiesterase to produce glycerol 3-phosphate. The latter consisted of L-glycerol 3-phosphate (ca 17%) and the D-isomer (ca. 83%). Ribonuclease N1 thus catalyzes an asymmetric synthesis.
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PMID:Synthesis of various phosphodiesters and phosphomonoesters with ribonuclease N. 18 80

Acid carboxypeptidase (EC 3.4.12.-) crystallized from culture filtrate of Penicillium janthinellum has been investigated for its use in carboxy-terminal sequence determination of Z-Gly-Pro-Leu-Gly, Z-Gly-Pro-Leu-Gly-Pro, angiotensin I, native lysozyme, native ribonuclease T1, and reduced S-carboxy-methyl-lysozyme. The examination indicated that proline and glycine were liberated from Z-Gly-Pro-Leu-Gly-Pro. At high enzyme concentration, the enzyme catalyzed complete sequential release of amino acids from the carboxy-terminal leucine to the amino-terminal aspartic acid of angiotensin I. The enzyme released the carboxy-terminal leucine from native lysozyme, however, no release of the threonine from native ribonuclease T1 was observed after a prolonged period of incubation with the enzyme. The sequence of the first nine carboxy-terminal residues of denatured lysozyme, leucine, arginine, S-carboxymethyl-cysteine, glycine, arginine, isoleucine, tryptophane, alanine, and glutamine, could be deduced unequivocally from a time release plot of an incubation mixture with the enzyme.
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PMID:Action of crystalline acid carboxypeptidase from Penicillium janthinellum. 23 51

Using an Escherichia coli overproducing strain secreting Aspergillus oryzae RNase T1, we have constructed and characterized mutants where amino acid residues in the catalytic center have been substituted. The mutants are His40----Thr, Glu58----Asp, Glu58----Gln, His92----Ala and His92----Phe. His92----Ala and His92----Phe mutants are inactive. On the basis of their kcat/Km values, the mutants Glu58----Asp and Glu58----Gln show 10% and 7% residual activity, relative to wild-type RNase T1, whereas the His40----Thr mutant shows 2% activity. The effect of amino acid substitutions on the enzymatic activity of RNase T1 lends further support for a mechanism where Glu58 (possibly activated by His40 and His92 act as general base and acid respectively; this is discussed in terms of the known three-dimensional structure of the enzyme.
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PMID:Studies on RNase T1 mutants affecting enzyme catalysis. 190 90

Coulombic interactions between charges on the surface of proteins contribute to stability. It is difficult, however, to estimate their importance by protein engineering methods because mutation of one residue in an ion pair alters the energetics of many interactions in addition to the coulombic energy between the two components. We have estimated the interaction energy between two charged residues, Asp-12 and Arg-16, in an alpha-helix on the surface of a barnase mutant by invoking a double-mutant cycle involving wild-type enzyme (Asp-12, Thr-16), the single mutants Thr----Arg-16 and Asp----Ala-12, and the double mutant Asp----Ala-12, Thr----Arg-16. The changes in free energy of unfolding of the single mutants are not additive because of the coulombic interaction energy. Additivity is restored at high concentrations of salt that shield electrostatic interactions. The geometry of the ion pair in the mutant was assumed to be the same as that in the highly homologous ribonuclease from Bacillus intermedius, binase, which has Asp-12 and Arg-16 in the native enzyme. The ion pair does not form a hydrogen-bonded salt bridge, but the charges are separated by 5-6 A. The mutant barnase containing the ion pair Asp-12/Arg-16 is more stable than wild type by 0.5 kcal/mol, but only a part of the increased stability is attributable to the electrostatic interaction. We present a formal analysis of how double-mutant cycles can be used to measure the energetics of pairwise interactions.
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PMID:Estimating the contribution of engineered surface electrostatic interactions to protein stability by using double-mutant cycles. 224 51

A bacteriophage lambda clone containing a 20-kb human DNA segment was isolated and found to harbor a cluster of four tRNA genes. An 8.2-kb HindIII subfragment encompassing the genes was cloned into pBR322 for restriction mapping and DNA sequence analysis. The genes were found to be arranged as two tandem pairs, separated by 3 kb. A proline tRNAAGG gene is separated from a leucine tRNAAAG gene by a 724-bp intergenic region in the first pair, and a second proline tRNAAGG gene is 316 bp from a threonine tRNAUGU gene in the second pair, with the leucine tRNA gene being of opposite polarity to the other three genes. A putative Alu-like element was found to occur within a 2.0-kb DNA fragment, at least 0.7 kb from the tRNA gene cluster. The coding sequences of the two proline tRNAAGG genes are identical. The coding regions of all four tRNA genes contain consensus internal split promoter sequences and do not have intervening sequences nor the CCA trinucleotide found in mature tRNAs. The 3'-flanking regions of these four tRNA genes have normal RNA polymerase III termination sites of at least four consecutive T nucleotides. No apparent homologies occur between the 5'-flanking regions of these genes. All four tRNA genes are accurately transcribed in an in vitro HeLa cell-free system, and the RNase T1 fingerprints of the mature-sized tRNA transcripts were found to be consistent with the DNA sequences of the genes.
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PMID:Nucleotide sequence and transcription of a human tRNA gene cluster with four genes. 355 25

The 6 S leader RNA transcript from the Escherichia coli threonine operon controlling region was synthesized in vitro using purified RNA polymerase and restriction fragment DNA templates. The terminated leader transcript was analyzed by RNase T1 digestion followed by electrophoresis on 20% polyacrylamide, 8 M urea gels. Oligonucleotides of 7, 8, 13, 15, and 35 bases in length were detected and correlated with the known DNA sequence. The kinetics of RNase T1 digestion indicated that the RNA forms extensive secondary structure, especially at the 3'-terminus of the transcript. The sites of transcription initiation were determined by labeling the 5'-end of the transcript with [gamma-32P]ATP or -GTP followed by direct RNA sequencing. The DNA sequence preceding the initiation site shows homology with the equivalent regions of other bacterial and bacteriophage promoters. The transcription termination sites were determined by mapping of the RNase T1 oligonucleotides arising from the 3'-terminus of the transcript. Comparison of the mobilities of the 3'-oligonucleotides with the mobilities of standards on 20% polyacrylamide, 8 M urea gels indicated that the RNA contains a heterogeneous 3'-terminus. The two predominant oligonucleotides were CU7 and CU8. The 3'-terminus of the transcript also contains a region of dyad symmetry immediately preceding a stretch of uridine residues, characteristic of other rho-independent transcripts. In addition, kinetic studies indicated that RNA polymerase pauses approximately 50 base pairs upstream from the site of termination. The pause site appears to be immediately distal to another region of dyad symmetry.
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PMID:Initiation, pausing, and termination of transcription in the threonine operon regulatory region of Escherichia coli. 627 52

1. RNase Ms, a base non-specific RNase from Aspergillus saitoi was reduced and carboxymethylated (RCM-RNase Ms). RCM-RNase Ms was hydrolyzed with trypsin, and the trypsin digests were then treated with chymotrypsin. Trypsin digests were also treated with Staphylococcus protease and with chymotrypsin, separately. 2. By the analyses of the amino acid sequences of the peptides formed, the alignment of these peptides in RCM-RNase Ms was determined. 3. From the digest of heat-denatured RNase Ms with Bacillus subtilis protease, two peptides containing disulfide bridges were isolated. From the analysis of these two peptides, the locations of the bridges were determined. 4. The amino acid sequence of RNase Ms was compared with those of RNase T1 (Asp. oryzae, guanine specific), RNase U1 (Ustilago sphaerogena, guanine specific) and RNase U2 (Ustilago sphaerogena, purine specific). There are very similar sequences between these for RNases irrespective of their differences in base specificity. These were, in RNase Ms, tripeptide sequence containing His39 (Tyr-Pro-His), the tetrapeptide containing Glu57 (Glu-Tyr-Pro-Ile), the hexapeptide containing Arg76 (Asp-Arg-Val-Ile-Phe-Asp) and the hexapeptide containing His 91 (Ile-Thr-His-Thr-Gly-Ala). The other sequences common for all four RNases are Tyr67, Phe100, and Cys103 in RNase Ms. Since among these peptides His39, Glu57, His91, and Arg76 in RNase Ms corresponded to His40, Glu58, His92, and Arg77 in RNase T1 which are known to be involved in the active site of RNase T1, the possible role of these amino acids in the active site of RNase Ms is discussed. 5. The sequence similarity of RNase Ms to that of RNase T1 was about 60% and to those of RNase U1 and RNase U2 was about 30%. 6. The details of the experimental evidence used to elucidate the amino acid sequence of RNase Ms are described in the supplemental miniprint.
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PMID:Primary structure of a minor ribonuclease from Aspergillus saitoi. 709 2

Two mutants of ribonuclease T1 (RNaseT1), [59-tyrosine]ribonuclease T1 (W59Y) and [45-tryptophan,59-tyrosine]ribonuclease T1 (Y45W/W59Y) possess between 150% and 190% wild-type activity. They have been crystallised as complexes of the inhibitor 2'-guanylic acid and analysed by X-ray diffraction at resolutions of 0.23 nm and 0.24 nm, respectively. The space group for both is monoclinic, P2(1), with two molecules/asymmetric unit, W59Y: a = 4.934 nm, b = 4.820 nm, c = 4.025 nm, beta = 90.29 degrees. Y45W/W59Y: a = 4.915 nm, b = 4.815 nm, c = 4.015 nm, beta = 90.35 degrees. Compared to wild-type RNaseT1 in complex with 2'-guanylic acid (2'GMP) both mutant inhibitor complexes indicate that the replacement of Trp59 by Tyr leads to a 0.04-nm inward shift of the single alpha-helix and to significant differences in the active-site geometry, inhibitor conformation and inhibitor binding. Calorimetric studies of a range of mutants [24-tryptophan]ribonuclease T1 (Y24W), [42-tryptophan]ribonuclease T1 (Y42W), [45-tryptophan]ribonuclease T1 (Y45W), [92-alanine]ribonuclease T1 (H92A) and [92-threonine]ribonuclease T1 (H92T) with and without the further mutation Trp59-->Tyr showed that mutant proteins for which Trp59 is replaced by Tyr exhibit slightly decreased thermal stability.
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PMID:X-ray crystallographic and calorimetric studies of the effects of the mutation Trp59-->Tyr in ribonuclease T1. 812 11

1. In order to understand the differences in pH optima and reaction rates of RNase A towards low molecular weight substrates and polymer substrates, the subsite structure of bovine pancreatic RNase A was studied. The kinetic studies of various sizes of oligouridylic acids showed that the size of the subsite is three nucleotides long. The kinetic studies on the inhibition of pUp, X-ray crystallographies of RNase A-ApC and pTp complexes, 31P-NMR studies on the binding of RNase A-pAp, and pTp showed the presence of P0, P2 and B3 sites. The location of the P0 site was assigned to be Lys66 by X-ray crystallography of the RNase A-pTp complex. The location of the P2 and/or P3/B3 site was determined by studying the enzymatic activities of several S-peptide analogs in which N-Leu was substituted for Lys7 and/or Lys1 coupled with S-protein toward various chain lengths of oligouridylic acids. The experiment suggested that P2 is Lys7 and P3/B3 is Lys1. 2. Several new pyrimidine base specific RNases were isolated and their primary structures were determined. They were two non-secretory RNases, a bovine liver alkaline RNase, a bovine brain RNase, and a bullfrog liver RNase. The bovine brain RNase has extra 16 amino acids at the C-terminus with O-glycosylated Ser. The bullfrog liver RNase was an extremely heat-stable RNase so far known. 3. Two new RNases belonging to RNase T1 family were isolated and their primary structures were elucidated. They were RNases isolated from Aspergillus saitoi and a mushroom (hiratake). The former RNase has a similar structure to RNase T1, but it was a base non-specific and guanylic acid preferential enzyme. From the results of X-crystallographic studies of this RNase, we suggested that the mechanism of RNase T1 RNase is essentialy a general acid-base catalysis between His40 and Glu58. 4. We isolated several fungal, plant and animal base non-specific acid RNases with a molecular mass about 24 kDa or more, and elucidated their primary structures. These RNases contain two sequences containing common 7-8 amino acid residues in common which include most of the amino acid residues important for the catalysis. Therefore, we proposed to designate these RNases as RNase T2 family RNase. On the basis of chemical modifications, kinetic studies and protein engineering studies of RNase Rh from Rhizopus niveus and RNase M from A. saitoi, we assigned that the catalytic site of RNase Rh consists of His46, His104, His109, Glu105, and Lys108. In the mechanism we proposed for RNase Rh, His46 and His109 work as a general acid and base catalysts. His104 was a phosphate binding site, and Glu105 and Lys108 might work to polarize a P=O bond of the substrate or stabilize the pentacovalent intermediate. However, in the reverse reaction of the transfer reaction step and the hydrolysis step of RNase Rh, His109 and His46 work as an acid and base catalyst, respectively. The X-ray crystallographic studies of RNase Rh, an RNase Rh-2'-AMP or d(ApC)complex, and the protein engineering studies of several mutant enzymes assigned the components of the major base recognition site (B1 site) and the minor base recognition site (B2 sites) of RNase Rh. The enzymatic studies of several mutant enzymes indicated that (i) Asp51 is very crucial for adenine base recognition, and the replacement of Asp51 by other amino acid, such as Thr, Ser, Glu, Asn makes RNase Rh more guanylic acid preferential, (ii) the replacement of Trp49 by Phe, and Tyr57 by Trp make the enzyme more pyrimidine and purine bases preferential, respectively. These trials are the first example of marked artificial change in the base specificity of RNases.
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PMID:[Structures and functions of ribonucleases]. 935 26

Differential scanning calorimetry, urea denaturation, and X-ray crystallography were combined to study the structural and energetic consequences of refilling an engineered cavity in the hydrophobic core of RNase T1 with CH(3), SH, and OH groups. Three valines that cluster together in the major hydrophobic core of T1 were each replaced with Ala, Ser, Thr, and Cys. Compared to the wild-type protein, all these mutants reduce the thermodynamic stability of the enzyme considerably. The relative order of stability at all three positions is as follows: Val > Ala approximately equal to Thr > Ser. The effect of introducing a sulfhydryl group is more variable. Surprisingly, a Val --> Cys mutation in a hydrophobic environment can be as or even more destabilizing than a Val --> Ser mutation. Furthermore, our results reveal that the penalty for introducing an OH group into a hydrophobic cavity is roughly the same as the gain obtained from filling the cavity with a CH(3) group. The inverse equivalence of the behavior of hydroxyl and methyl groups seems to be crucial for the unique three-dimensional structure of the proteins. The importance of negative design elements in this context is highlighted.
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PMID:Hydrophobic core manipulations in ribonuclease T1. 1151 91

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