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)

Molecular dynamics simulations were performed on free RNase T1 and the 2'GMP-RNase T1 complex in vacuum and with water in the active site along with crystallographically identified waters, allowing analysis of both active site and overall structural and dynamics changes due to the presence of 2'GMP. Differences in the active site include a closing in the presence of 2'GMP, which is accompanied by a decrease in mobility of active site residues. The functional relevance of the active site fluctuations is discussed. 2'GMP alters the motion of Tyr-45, suggesting a role for that residue in providing a hydrophobic environment for the protein-nucleic acid interactions responsible for the specificity of RNase T1. The presence of 2'GMP causes a structural change of the C-terminus of the alpha-helix, indicating the transmission of structural changes from the active site through the protein matrix. Overall fluctuations of both the free and 2'GMP enzyme forms are in good agreement with X-ray temperature factors. The motion of Trp-59 is influenced by 2'GMP, indicating differences in enzyme dynamics away from the active site, with the calculated changes following those previously seen in time-resolved fluorescence experiments.
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PMID:Molecular dynamics simulations of ribonuclease T1: comparison of the free enzyme and the 2' GMP-enzyme complex. 255 78

Molecular dynamics simulations in vacuum and with a water sphere around the active site were performed on the 2'GMP-RNase T1 complex. The presence of water led to the maintenance of the 2'-GMP-RNase T1 interactions as compared to the X-ray structure, including the hydrogen bonds implicated in the enzyme-inhibitor recognition process. The sidechain of His92 in the molecular dynamics water simulation, however, hydrogen bonds directly to the phosphate of 2'GMP in contrast to the X-ray structure but in support of the role of that residue in the enzyme's catalytic mechanism. Fluctuations of active-site residues are not strongly influenced by water, possibly owing to the exclusion of water by the bound 2'GMP, which did show an increase in mobility. Analysis of the 2'GMP-RNase T1 interactions versus time reveal an equilibrium fluctuation in the presence of water, leading to a less favorable 2'GMP-RNase T1 interaction energy, suggesting a possible relationship between picosecond fluctuations and inhibitor dissociation occurring in the millisecond time domain.
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PMID:Molecular dynamics simulations of ribonuclease T1. Effect of solvent on the interaction with 2'GMP. 285 69

The tryptophyl fluorescence of ribonuclease T1 decays monoexponentially at pH 5.5, tau = 4.04 ns but on increasing pH, a second short-lived component of 1.5 ns appears with a midpoint between pH 6.5 and 7.0. Both components have the same fluorescence spectrum. Acrylamide quenches both fluorescence components, and the short-lived component is quenched fivefold faster than the predominant long component. Binding of the substrate analogue 2'-guanylic acid at pH 5.5 quenches the fluorescence by 20% and introduces a second decay component, tau = 1.16 ns. Acrylamide quenches both tryptophyl decay components, with similar quenching rates. The fluorescence anisotropy decay of ribonuclease T1 was consistent with a molecule the size of ribonuclease T1 surrounded by a single layer of water at pH 7.4, even though the anisotropy decay at pH 5.5 deviated from Stokes-Einstein behavior. The fluorescence data were interpreted with a model where the tryptophyl residue exists in two conformations, remaining in a hydrophobic pocket. The acrylamide quenching is interpreted with electron transfer theory and suggests that one conformer has the nearest atom approximately 3 A from the protein surface, and the other, approximately 2 A.
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PMID:Picosecond time-resolved fluorescence of ribonuclease T1. A pH and substrate analogue binding study. 303 4

Molecular dynamics simulations were performed on ribonuclease T1 (RNase T1; EC 3.1.27.3) to determine a structure for the free enzyme. Simulations starting with the X-ray coordinates for the 2'GMP-RNase T1 complex were done in vacuo and with an 18-A water ball around the active site using stochastic boundary conditions to understand the influence of water on both the structure and fluctuations of the enzyme. Removal of 2'GMP caused structural changes in the loop regions, including those directly interacting with the bound inhibitor in the crystal structure, while regions of secondary structure were less affected. The presence of solvent in the simulation damped the structural changes observed, which may be related to the use of full charges in both simulations. Fluctuations were also affected by the water, which generally increased both at the surface and in the interior of the protein. The active site in vacuo collapsed upon itself, forming a number of protein-protein hydrogen bonds leading to larger structural changes and lowered fluctuations while the presence of water kept the active site open, minimized structural changes, and increased fluctuations. Such fluctuations in the active site may be important for the binding of inhibitors or substrates to the enzyme. Lastly, results from the water simulation allow the prediction of a motion for a hypothetical tryptophan at position 45, which can ultimately be tested experimentally via time-resolved fluorescence using a site-specific mutant of the enzyme.
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PMID:Molecular dynamics simulations of ribonuclease T1: analysis of the effect of solvent on the structure, fluctuations, and active site of the free enzyme. 313 27

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

The effect of hydrostatic pressure (0-2.6 kbar) on the acrylamide quenching of the fluorescence of indole derivatives and several single-tryptophan-containing proteins has been studied using phase fluorometry at 25 degrees C. For the model system, N-acetyl-L-tryptophanamide in water, there is essentially no pressure dependence of the quenching rate constant, kappa q. For the internal Trp residue of ribonuclease T1 and cod parvalbumin, there also is essentially no pressure dependence of the apparent kappa q at low pressure. Thus, the activation volume, delta V not equal to, for these quenching processes is approximately zero. Such small delta V not equal to values are expected for diffusion-limited reactions in water at this temperature. The low, apparent delta V not equal to values for the globular proteins characterize these quenching processes as involving very small amplitude fluctuations in the protein structures. Only for the poised tetramer in equilibrium monomer equilibrium of melittin were we able to observe a significant effect of pressure on kappa q and this is due to the pressure-induced shift in the equilibrium position.
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PMID:Pressure dependence of fluorescence quenching reactions in proteins. 323 8

Flocculent densities appear in the mitochondrial matrix during ischemic damage. These densities were examined in kidneys after 2 hours of autolysis. The samples were embedded in water-miscible glycol methacrylate (GMA). Ultrathin sections on copper grids were digested with pronase, trypsin, ribonuclease T1, various phospholipases (A2, C, D), lipase, and desoxyribonuclease I. For statistical analysis the mean number (+/- SD) of densities per mitochondrion was determined in tubular epithelial cells. A statistically significant (p less than 0.001) decrease in the number of densities was apparent after treatment with pronase (75.5%) of the densities digested completely) and with trypsin (43.3% of the densities digested completely). Digestion with other enzymes did not significantly decrease the number of densities. This study provides quantitative support for the hypothesis that flocculent densities are composed of proteins, most probably mitochondrial membrane proteins or matrix proteins. The results do not support the hypothesis that RNA, neutral lipids, phospholipids or DNA are major constituents of these structures.
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PMID:Mitochondrial flocculent densities in ischemia. Digestion experiments. 666 82

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

The dependence of fluorescence emission maxima of L-tryptophan and single-tryptophan-containing proteins (ribonuclease T1, melittin, and parvalbumin) on excitation wavelength has been studied in reversed micelle systems of sodium bis(2-ethyl-1-oxyl) sulfosuccinate (AOT). No effect of fluorescence maximum shift for different excitation wavelengths is observed for ribonuclease T1, in which a single tryptophan residue is located in the nonrelaxating, nonpolar protein interior. L-Tryptophan and the rest of the studied proteins, which contain single tryptophan residues exposed to the solvent, exhibit the dipolar relaxational processes of partly immobilized water molecules in micelles. This effect depends on the molar H2O/AOT ratio. Circular dichroism measurements prove that there have been no structural changes of the studied proteins in micellar systems. The results provide information about dynamic relaxational processes in proteins.
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PMID:Red-edge excitation fluorescence spectroscopy of proteins in reversed micelles. 752 18

An approach is described for extending free energy calculations to take into account the pH dependence of the relative binding of ligands to an enzyme or other receptor protein. The method is based on the calculation of the free energy difference for a single protonation state via the thermodynamic cycle simulation approach followed by inclusion of all possible protonation states of the enzyme and the inhibitor by use of a macroscopic continuum dielectric (Poisson-Boltzmann) model. A detailed formulation of the combined model is presented. It involves solution of the multiple equilibrium problem and makes use of the calculated pKa values of all titrating groups on both enzyme and ligand. The method is illustrated by calculations of the pH dependence of the differential binding of the inhibitors 2'GMP and 3'GMP to ribonuclease T1. A free energy simulation of the differential binding is made for a given protonation state of the enzyme and inhibitor. Although only qualitative agreement with experiment is obtained, the results provide insights concerning the interactions involved. The pH dependence of the binding is calculated by using the protonation state of the residues from the free energy simulation as the standard state for a Poisson-Boltzmann calculation. Information is obtained concerning the pKa values of the titrating amino acids in the free, 2'GMP and 3'GMP bound enzyme forms of RNase T1 and the difference in the pH dependence of the binding of 2'GMP and 3'GMP to RNase T1. The contributions of different types of interactions (e.g. protein residues versus solvent) to the free energy differences are examined. A free energy simulation of the pKa shift of Glu58 shows that it is important to consider both carboxyl oxygen atoms as possible protonation sites since they may behave very differently in a protein. It is found in the protein that the interactions with the solvent favor the neutral (protonated) state of Glu58. This contrasts sharply with the solution behavior, where the solvent favors the charged state. Analysis of the results shows that the interactions of bound water with other protein residues leads to the observed effect. Comparisons are made with a continuum calculation that uses the charged state employed in the free energy simulation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:pH dependence of binding reactions from free energy simulations and macroscopic continuum electrostatic calculations: application to 2'GMP/3'GMP binding to ribonuclease T1 and implications for catalysis. 772 31


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