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)

The determination of RNA sequences using base- specific enzymatic cleavages is a well established method. Different synthetic RNA molecules were analyzed for uniformity of degradation by RNase T1, U2, A and PhyM under reaction conditions compatible with Matrix-Assisted Laser Desorption/Ionization Mass Spectrometry (MALDI-MS), to identify the positions of G, A and pyrimidine residues. In order to get a complete set of fragments derived from cleavage at every phosphodiester bond, the samples were also subjected to a limited alkaline hydrolysis. Additionally, the 5'-terminus fragments of a 49mer RNA transcript were isolated by way of 5'-biotinylation and streptavidin-coated magnetic beads (Dynal), followed by a RNase U2digestion. MALDI-MS of the generated fragments is presented as an efficient technique for a direct read out of the nucleotide sequence.
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PMID:Matrix-assisted laser desorption/ionization mass spectrometry (MALDI) of endonuclease digests of RNA. 911 63

Members of the microbial guanyl-specific ribonuclease family catalyse the endonucleolytic cleavage of single-stranded RNA in a two-step reaction involving transesterification to form a 2',3'-cyclic phosphate and its subsequent hydrolysis to yield the respective 3'-phosphate. The extracellular ribonuclease from Bacillus intermedius (binase, RNase Bi) shares a common mechanism for RNA hydrolysis with mammalian RNases. Two catalytic residues in the active site of binase, Glu72 and His101, are thought to be involved in general acid-general base catalysis of RNA cleavage. Using site-directed mutagenesis, binase mutants were produced containing amino acid substitutions H101N and H101T and their catalytic properties towards RNA, poly(I), poly(A), GpC and guanosine 2',3'-cyclic phosphate (cGMP) substrates were studied. The engineered mutant proteins are active in the transesterification step which produces the 2',3'-cyclic phosphate species but they have lost the ability to catalyse hydrolysis of the cyclic phosphate to give the 3' monophosphate product.
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PMID:RNA cleavage without hydrolysis. Splitting the catalytic activities of binase with Asn101 and Thr101 mutations. 915 77

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

Ribonucleases Sa, Sa2, and Sa3 are three small, extracellular enzymes produced by different strains of Streptomyces aureofaciens with amino acid sequences that are 50% identical. We have studied the unfolding of these enzymes by heat and urea to determine the conformational stability and its dependence on temperature, pH, NaCl, and the disulfide bond. All three of the Sa ribonucleases unfold reversibly by a two-state mechanism with melting temperatures, Tm, at pH 7 of 48.4 degrees C (Sa), 41.1 degrees C (Sa2), and 47.2 degrees C (Sa3). The Tm values are increased in the presence of 0.5 M NaCl by 4.0 deg. C (Sa), 0.1 deg. C (Sa2), and 7.2 deg. C (Sa3). The Tm values are decreased by 20.0 deg. C (Sa), 31.5 deg. C (Sa2), and 27.0 deg. C (Sa3) when the single disulfide bond in the molecules is reduced. We compare these results with similar studies on two other members of the microbial ribonuclease family, RNase T1 and RNase Ba (barnase), and with a member of the mammalian ribonuclease family, RNase A. At pH 7 and 25 degrees C, the conformational stabilities of the ribonucleases are (kcal/mol): 2.9 (Sa2), 5.6 (Sa3), 6.1 (Sa), 6.6 (T1), 8.7 (Ba), and 9.2 (A). Our analysis of the stabilizing forces suggests that the hydrophobic effect contributes from 90 to 110 kcal/mol and that hydrogen bonding contributes from 70 to 105 kcal/mol to the stability of these ribonucleases. Thus, we think that the hydrophobic effect and hydrogen bonding make large but comparable contributions to the conformational stability of these proteins.
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PMID:Conformational stability and thermodynamics of folding of ribonucleases Sa, Sa2 and Sa3. 963 16

In Euplotes crassus, telomerase is responsible for telomere maintenance during vegetative growth and de novo telomere synthesis during macronuclear development. Here we show that telomerase in the vegetative stage of the life cycle exists as a 280-kD complex that can add telomeric repeats only onto telomeric DNA primers. Following the initiation of macronuclear development, telomerase assembles into larger complexes of 550 kD, 1600 kD, and 5 MD. In the 1600-kDa and 5-MDa complexes, telomerase is more processive than in the two smaller complexes and can add telomeres de novo onto nontelomeric 3' ends. Assembly of higher order telomerase complexes is accompanied by an extended region of RNase V1 and RNase T1 protection in the telomerase RNA subunit that is not observed with telomerase from vegetatively growing cells. The protected residues encompass a highly conserved region previously proposed to serve as a platform for formation of higher order structures. These findings provide the first direct demonstration of developmentally regulated higher order telomerase complexes with unique biochemical and structural properties.
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PMID:Developmentally programmed assembly of higher order telomerase complexes with distinct biochemical and structural properties. 974 68

The electrostatic behavior of titrating groups in alpha-sarcin was investigated using 1H NMR spectroscopy. A total of 209 chemical shift titration curves corresponding to different protons in the molecule were determined over the pH range of 3.0-8.5. Nonlinear least-squares fits of the data to simple relationships derived from the Henderson-Hasselbalch equation led to the unambiguous determination of pKa values for all glutamic acid and histidine residues, as well as for the C-terminal carboxylate and most of the aspartic acids in the free enzyme. The ionization constants of catalytically relevant histidines, His50 and His137, and glutamic acid, Glu96, in the alpha-sarcin-2'-GMP complex were also determined. The pKa values of 15 ionizable groups (C-carboxylate, six aspartic acids, four glutamic acids, and four histidines) were found to be close to their normal values. On the other hand, a number of side chain groups, including those in the active center, showed pKa values far from their intrinsic values. Thus, the pKa values for active site residues His50, Glu96, and His137 were 7.7, 5.2, and 5.8 in the free enzyme and 7.6, approximately 4.8, and 6.8 in the alpha-sarcin-2'-GMP complex, respectively. The pKa values and the activity profile against ApA, as a function of pH, are in agreement with the proposed enzymatic mechanism (in common with RNase T1 and the family of the microbial ribonucleases), in which Glu96 and His137 act as a general base and general acid, respectively. In almost all microbial ribonucleases, a Phe-His interaction is present, which affects the pKa of one of the His residues at the active site (His137). The absence of this interaction in alpha-sarcin would explain the lower pKa value of this His residue, and provides an explanation for the decreased RNase activity of this protein as compared to those of other microbial ribonucleases.
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PMID:Characterization of pKa values and titration shifts in the cytotoxic ribonuclease alpha-sarcin by NMR. Relationship between electrostatic interactions, structure, and catalytic function. 984 92

Effects of medium viscosity on kinetic parameters of poly(U) hydrolysis catalyzed by RNase from Bac. intermedius 7P (binase) were studied in solutions of sucrose (4-50 wt. %) and glycerol (35-62 wt. %) in Tris--sodium acetate buffer (pH 7.5) at 25 degreesC. The rate constant of reaction kcat was practically unchanged over a wide range of viscosities (1-15 cP for sucrose and 2.5-3 cP for glycerol). In glycerol solutions, kcat slightly increased with viscosity increase from 4 to 10 cP. Addition of NaCl to the buffer medium resulted in an inhibitory effect of Na+ on kcat, prevented by 50% sucrose or 60% glycerol. It is concluded that binase-catalyzed poly(U) cleavage occurs through a "tense"-substrate mechanism, similarly to reactions catalyzed by alpha-chymotrypsin, trypsin, and laccase.
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PMID:Effects of medium viscosity on kinetics of the enzymatic reaction catalyzed by bacterial RNase 986 66

This paper describes the use of fluorescence quenching and dequenching to analyze molecular interactions of RNA in vitro and in vivo. Fluorescein-labeled ribonucleotide was incorporated into an RNA substrate by in vitro transcription. The fluorescence quantum yield of the intact RNA was reduced by intramolecular quenching. When the RNA was degraded by ribonuclease digestion, the quantum yield increased by approximately 50%, reflecting dequenching due to separation of proximate fluorophores. Dequenching was dependent on the concentration of enzyme and substrate and was inhibited by the ribonuclease inhibitor RNasin. Comparable rates of dequenching were observed with RNase A and RNase T1. Dequenching provides a sensitive, quantitative, and convenient assay for RNA degradation. When fluorescent RNA was microinjected into cells in culture the intracellular fluorescence declined gradually with time after injection reflecting "superquenching: due to intermolecular interactions between the injected RNA and intracellular components. Capped RNA exhibited greater superquenching than uncapped RNA. Superquenching provides a sensitive, quantitative, and specific assay with subcellular resolution for intermolecular interactions of RNA in vivo. When RNase was injected into the same cells, fluorescence increased by approximately 50%, indicating that fluorescence dequenching due to RNA degradation can be measured in vivo as well as in vitro.
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PMID:Fluorescence quenching and dequenching analysis of RNA interactions in vitro and in vivo. 986 74

Biosynthesis of extracellular alkaline guanyl-specific RNase by Bacillus circulans (RNase Bci) was studied. Synthesis of the enzyme by the culture started in the late exponential phase and was inhibited by inorganic phosphate and glucose, in contrast to the biosynthesis of its structural and functional homologue, RNase Ba (barnase) of B. amyloliquefaciens. It is suggested that differences in the regulation of the biosynthesis of RNase Bci and Ba are related to different structures of their gene promoters.
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PMID:[Biosynthesis of extracellular guanyl-specific ribonuclease from Bacillus circulans]. 989 Dec 94

Attempts to modify the guanine specificity of ribonuclease T1 (RNase T1) by rationally designed amino acid substitutions failed so far. Therefore, we applied a semirational approach by randomizing the guanine binding site. A combinatorial library of approximately 1.6 million RNase T1 variants containing permutations of 6 amino acid positions within the recognition loop was screened on RNase indicator plates. The specificity profiles of 180 individual clones showing RNase activity revealed that variant K41S/N43W/N44H/Y45A/E46D (RNaseT1-8/3) exhibits an altered preference toward purine nucleotides. The ApC/GpC preference in the cleavage reaction of this variant was increased 4000-fold compared to wild-type. Synthesis experiments of dinucleoside monophosphates from cytidine and the corresponding 2'3'-cyclic diesters using the reverse reaction of the transesterification step showed a 7-fold higher ApC synthesis rate of RNase 8/3 than wild-type, whereas the GpC synthesis rates for both enzymes were comparable. This study shows that site-directed random mutagenesis is a powerful additional tool in protein design in order to achieve new enzymatic specificities.
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PMID:Modification of ribonuclease T1 specificity by random mutagenesis of the substrate binding segment. 993 Oct


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