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)

Recognition by ribonuclease T1 of guanine bases via multidentate hydrogen bonding and stacking interactions appears to be mediated mainly by a short peptide segment formed by one stretch of a heptapeptide, Tyr42-Asn43-Asn44-Tyr45-Glu46-Gly47- Phe48. The segment displays a unique folding of the polypeptide chain--consisting of a reverse turn, Asn44-Tyr45-Glu46-Gly47, stabilized by a hydrogen-bond network involving the side chain of Asn44, the main-chain atoms of Asn44, Gly47 and Phe48 and one water molecule. The segment is connected to the C terminus of a beta-strand and expands into a loop region between Asn43 and Ser54. Low values for the crystallographic thermal parameters of the segment indicate that the structure has a rigidity comparable to that of a beta-pleated sheet. Replacement of Asn44 with alanine leads to a far lower enzymatic activity and demonstrates that the side chain of Asn44 plays a key role in polypeptide folding in addition to a role in maintaining the segment structure. Substitution of Asn43 by alanine to remove a weak hydrogen bond to the guanine base destabilized the transition state of the complex by 6.3 kJ/mol at 37 degrees C. In contrast, mutation of Glu46 to alanine to remove a strong hydrogen bond to the guanine base caused a destabilization of the complex by 14.0 kJ/mol. A double-mutant enzyme with substitutions of Asn43 by a histidine and Asn44 by an aspartic acid, to reproduce the natural substitutions found in ribonuclease Ms, showed an activity and base specificity similar to that of the wild-type ribonuclease Ms. The segment therefore appears to be well conserved in several fungal ribonucleases.
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PMID:Conformational properties of the guanine-binding site of ribonuclease T1 inferred from the X-ray structure and protein engineering. 315 Oct 17

Ribonuclease T1 (RNase T1) cleaves the phosphodiester bond of RNA specifically at the 3'-end of guanosine. 2'-guanosinemonophosphate (2'-GMP) acts as inhibitor for this reaction and was cocrystallized with RNase T1. X-Ray analysis provided insight in the geometry of the active site and in the parts of the enzyme involved in the recognition of guanosine. RNase T1 is globular in shape and consists of a 4.5 turns alpha-helix lying "below" a four-stranded antiparallel beta-sheet containing recognition center as well as active site. The latter is indicated by the position of phosphate and sugar residues of 2'-GMP and shows that Glu58, His92 and Arg77 are active in phosphodiester hydrolysis. Guanine is recognized by a stretch of protein from Tyr42 to Tyr45. Residues involved in recognition are peptide NH and C = O, guanine O6 and N1H which form hydrogen bonds and a stacking interaction of Tyr45 on guanine. Although, on a theoretical basis, many specific amino acid-guanine interactions are possible, none is employed in the RNase T1.guanine recognition.
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PMID:Crystallographic study of mechanism of ribonuclease T1-catalysed specific RNA hydrolysis. 608 61

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.
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PMID:Specific protein-nucleic acid recognition in ribonuclease T1-2'-guanylic acid complex: an X-ray study. 628 78

The 270-MHz 1H NMR spectra and fluorescence of ribonuclease T1 and carboxymethylated ribonuclease T1 were measured in aqueous solution. Histidine C4 proton resonances were assigned to individual residues. From the pH dependences of the chemical shifts of histidine C2 and C4 protons, the pKa values of histidine residues were obtained by the non-linear least-squares method. The hydrogen leads to deuterium exchange rates of histidine C2 protons were determined as a measure of the accessibility of histidine residues to the solvent. Each histidine residue of ribonuclease T1 was found to interact with a carboxylate group of an aspartic or glutamic acid residue; in particular, His-40 was shown to interact with Glu-58. Upon carboxymethylation of Glu-58, His-92 and His-27 are more shielded from the solvent while His-40 remains exposed to the solvent. The 67.9-MHz 13C NMR spectra were measured for the 13C-enriched preparation of carboxymethylated ribonuclease T1. From the pH dependence of 13C chemical shift, the pKa value of the carboxymethylated Glu-58 was found to be unusually low, suggesting the formation of an ionic or hydrogen bond between this carboxymethyl group and a positively charged group, possibly of Arg-77.
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PMID:Nuclear magnetic resonance study on the microenvironments of histidine residues of ribonuclease T1 and carboxymethylated ribonuclease T1. 678 55

The crystal structure of purine-specific ribonuclease (RNase) U2 from Ustilago sphaerogena has been solved by the molecular replacement methods using RNase T1 as a search model. The structure, with 114 amino acid residues, 141 water molecules, and a sulfate ion, is refined to an R factor of 0.143 at 1.8 A resolution. As evidenced by the electron densities, residues 49 and 50 are revised to Glu 49 and Asp 50, respectively, and also Asp 45 is identified as a beta-isomerized form to L-isoaspartate with a beta-peptide linkage. RNase U2 consists of a beta-hairpin at residues from 7 to 14, a 4.4-turn alpha-helix from 16 to 32, a central beta-sheet with five strands, and a protruding beta-turn from 74 to 77. As for the catalytic site residues, His 41, Glu 62, and Arg 85 are located as constituents of the central beta-sheet, and Tyr 39 and His 101 are situated at either end of the beta-sheet. The side chains of Tyr 39, Glu 62, Arg 85, and His 101 are hydrogen-bonded to the sulfate ion which marks the RNA phosphate position. Though the side chain of His 41 is pointing away from the sulfate, small conformational adjustments of His 41 enable the side chain to interact with either the phosphate or the ribose group of RNA. The loop region from Tyr 44 to Asp 50 is ascribed to the base recognition site where Glu 49 is involved in adenine recognition. beta-Isomerized Asp 45 suggests that this region is conformationally flexible and alterable.
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PMID:Crystal structure of Ustilago sphaerogena ribonuclease U2 at 1.8 A resolution. 749 61

To address a number of conflicting reports in the literature, we undertook an infrared spectroscopic study to test for the presence of native-like secondary structures in thermally denatured ribonuclease A. Ribonuclease A does not aggregate at high temperatures, and the infrared spectrum shows a completely featureless amide I band contour. Using 13C-labeled urea, we were also able to obtain the infrared spectrum of the chemically denatured protein, which is practically identical with that of the heat-denatured protein. To the best of our knowledge, this is the first study that uses 13C-labeled urea as a chemical denaturant which circumvents the problem encountered with the strong absorption of urea in the conformation-sensitive amide I region of proteins; it opens up the possibility of investigating protein folding/unfolding processes in the presence of high concentrations of chemical denaturants. From an analysis of the amide I region of the infrared spectra of thermally and chemically denatured RNase A, it was concluded that heat-denatured ribonuclease A does not contain any significant amount of authentic hydrogen-bonded secondary structures. Furthermore, a comparison of the infrared spectra of ribonuclease A with those of ribonuclease T1 demonstrates that in spite of major differences between their native structures there are practically no differences between their heat-denatured states. This would not be expected if there were residual native-like secondary structures in the thermally denatured state of one or both of these proteins.
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PMID:Ribonuclease A revisited: infrared spectroscopic evidence for lack of native-like secondary structures in the thermally denatured state. 757 55

The crystal structure of RNase T1 complexed with 3'-GMP has been determined. The glycosyl conformation of 3'-GMP is in the syn conformation, and the ribose adopts the O4'-endo pucker. This observed pucker is different from that in any complex structures of RNase T1. In the present complex, this energetically unfavorable conformation is stabilized by the water molecule with the bridged hydrogen bonds between the O2' and the O3' atoms of the ribose. The guanine base is recognized in the same manner as observed in the complex of 2'-GMP. The 2'-hydroxyl group of the ribose shows a tight hydrogen bond to both His-40 and Glu-58 with the suitable geometry for the proton transfer. These hydrogen bonds suggest that the two residues can participate directly in the proton transfer. His-92 is hydrogen bonded to two the proton transfer. His-92 is hydrogen bonded to two oxygen atoms of the phosphate group. Based on the geometry in the active site, the O1P atom may correspond to the O5' atom of the leaving nucleotide in the phosphoryl transfer or a water molecule as a nucleophile in the hydrolysis reaction. In the present complex, the conformations of the 3'-GMP molecule and the side chains of the catalytic residues would be represented as the conformation before the phosphoryl transfer reaction and/or after the hydrolysis reaction.
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PMID:Crystal structure of RNase T1 complexed with the product nucleotide 3'-GMP. Structural evidence for direct interaction of histidine 40 and glutamic acid 58 with the 2'-hydroxyl group of the ribose. 791 96

An efficient automatic method has been developed for docking a ligand molecule to a protein molecule. The method can construct energetically favorable docking models, considering specific interactions between the two molecules and conformational flexibility in the ligand. In the first stage of docking, likely binding modes are searched and estimated effectively in terms of hydrogen bonds, together with conformations in part of the ligand structure that includes hydrogen bonding groups. After that part is placed in the protein cavity and is optimized, conformations in the remaining part are also examined systematically. Finally, several stable docking models are obtained after optimization of the position, orientation and conformation of the whole ligand molecule. In all the screening processes, the total potential energy including intra- and intermolecular interaction energy, consisting of van der Waals, electrostatic and hydrogen bonding energies, is used as the index. The characteristics of our docking method are high accuracy of the results, fully automatic generation of models and short computational time. The efficiency of the method was confirmed by four docking trials using two enzyme systems. In two attempts to dock methotrexate to dihydrofolate reductase and 2'-GMP to ribonuclease T1, the exact structures of complexes in crystals were reproduced as the most stable docking models, without any assumptions concerning the binding modes and ligand conformations. The most stable docking models of dihydrofolate and trimethoprim, respectively, to dihydrofolate reductase were also in good agreement with those suggested by experiment. In all test cases, it was shown that our method can accurately predict the correct docking structures, discriminating the correct model from incorrect ones. The efficiency of our method was further tested from the viewpoint of ability to predict the relative stability of the docking structures of two triazine derivatives to dihydrofolate reductase. Our docking method provides a useful tool for rational drug design and investigations of biochemical reaction mechanisms.
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PMID:Rational automatic search method for stable docking models of protein and ligand. 793 57

We undertook a detailed comparative analysis of the infrared spectra of wild-type ribonuclease T1 and three mutants: two single mutants, Tyr-45-->Trp (Y45W) and Trp-59-->Tyr (W59Y), and a double mutant, Tyr-45-->Trp/Trp-59-->Tyr (Y45W/W59Y). These mutants were selected because they are known to affect the activity of the enzyme. The structural differences were evaluated by using peptide backbone and side-chain "marker" bands as conformation-sensitive monitors. All mutations lead to a decrease of the thermal transition temperature, though the mutation Tyr-45-->Trp affects the Tm to a lesser degree than the replacement of Trp-59 by Tyr, both in the single (W59Y) and in the double (Y45W/W59Y) mutant. Small changes in the protein backbone conformation and in the microenvironment of certain amino acids, induced by the point mutations, could be detected. In particular, we found subtle differences in the hydrogen bonding pattern of the beta-strands in the mutants W59Y and Y45W/W59Y, compared to that in wild-type RNase T1 and in the mutant Y45W. Practically identical spectra in the amide I region were obtained for the double mutant Y45W/W59Y and the single mutant W59Y, demonstrating that it is the change from Trp to Tyr in position 59 (located at the interface between the alpha-helix and a beta-strand) which affects the overall protein conformation. The mutation Tyr to Trp in position 45, on the other hand, has practically no impact on the polypeptide backbone conformation.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Impact of point mutations on the structure and thermal stability of ribonuclease T1 in aqueous solution probed by Fourier transform infrared spectroscopy. 807 73

The chemical-shift dependences of the proton signals of the guanosine and uridine moieties were measured as a function of the relative amount of GpcU complexed with RNase Pb1 (EC 3.1.27.3). The equal values of the chemical-shift changes of the guanosine C8-protons on complex formation between GpcU and RNase Pb1 and that of the 3'-GMP and RNase Pb1 allow to conclude that the guanosine base is bound in the same manner in these protein-ligand complexes. The guanosine moiety of GpcU is also most probably bound in the syn-conformation. The absence of changes in both the linewidths and the chemical shifts of the C1', C5 and C6-proton signals of the uridine on complex formation indicates that the uridine moiety of the dinucleoside phosphonate is not immobilized in the complex. The pH dependences of the chemical shifts of the C2-protons of the histidine-imidazole ring of RNase Pb1 and that of the 31P of GpcU in the RNase complex were studied. The results suggest that there is a direct interaction between the phosphonate group of the ligand and the protonated imidazole ring of His-90. The side groups of His-38 and Glu-56 are hydrogen bonded to each other at neutral pH and they are located in the vicinity of the phosphonate group of GpcU. When the carboxyl group of Glu-56 is protonated the His-38 imidazole ring forms a new hydrogen bond with one of the phosphoryl oxygens of the phosphonate group. On the basis of these results we propose the mechanism of action of RNase Pb1 which is probably also true for RNase T1.
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PMID:NMR studies of a complex of RNAse from Penicillium brevicompactum with dinucleoside phosphonate and the implications for the mechanism of enzyme action. 810 37


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