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)

To investigate the pH dependence of the conformational stability of ribonucleases A and T1, urea and guanidine hydrochloride denaturation curves have been determined over the pH range 2-10. The maximum conformational stability of both proteins is about 9 kcal/mol and occurs near pH 4.5 for ribonuclease T1 and between pH 7 and 9 for ribonuclease A. The pH dependence suggests that electrostatic interactions among the charged groups make a relatively small contribution to the conformational stability of these proteins. The dependence of delta G on urea concentration increases from about 1200 cal mol-1 M-1 at high pH to about 2400 cal mol-1 M-1 at low pH for ribonuclease A. This suggests that the unfolded conformations of RNase A become more accessible to urea as the net charge on the molecule increases. For RNase T1, the dependence of delta G on urea concentration is minimal near pH 6 and increases at both higher and lower pH. An analysis of information of this type for several proteins in terms of a model developed by Tanford [Tanford, C. (1964) J. Am. Chem. Soc. 86, 2050-2059] suggests that the unfolded states of proteins in urea and GdnHCl solutions may differ significantly in the extent of their interaction with denaturants. Thus, the conformations assumed by unfolded proteins may depend to at least some extent on the amino acid sequence of the protein.
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PMID:pH dependence of the urea and guanidine hydrochloride denaturation of ribonuclease A and ribonuclease T1. 211 Apr 72

The role of tryptophan residues in the stability of proteins was studied by ozone oxidation, which causes a small change in the tryptophan side chain. Trp 187 of the constant fragment of a type lambda immunoglobulin light chain, Trp 59 of ribonuclease T1, and Trp 62 of hen egg white lysozyme were oxidized specifically by ozone to N'-formylkynurenine or kynurenine. Judging from their circular dichroic and fluorescence spectra, these modified proteins were found to be the same as those of the respective intact proteins. However, even the slight modification of a single tryptophan residue produced a large decrease in the stability of these proteins to guanidine hydrochloride and heat. The smaller the extent of exposure of the tryptophan residue, the greater the effect of the modification on the stability. The formal kinetic mechanism of unfolding and refolding by guanidine hydrochloride of the CL fragment was not altered by tryptophan oxidation, but the rate constants for unfolding and refolding changed. The thermal unfolding transitions were analyzed to obtain the thermodynamic parameters. The enthalpy and entropy changes for the modified proteins were larger than the respective values for the intact proteins.
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PMID:Chemical modification of tryptophan residues and stability changes in proteins. 212 74

Guanidine resistance (gr) mutations of foot-and-mouth disease virus were mapped by recombining pairs of temperature-sensitive mutants belonging to different subtypes. In each cross, one parent possessed a gr mutation. Recombinants were isolated by selection at the nonpermissive temperature and assayed for the ability to grow in the presence of guanidine. From the progeny of three crosses, four different types of recombinant were distinguished on the basis of protein composition and RNA fingerprint. The sequences of the RNase T1-resistant oligonucleotides were determined and located in the full-length sequence of foot-and-mouth disease virus. The resulting maps show that (i) each recombinant was generated by a single genetic crossover, and (ii) both of the gr mutations studied were located within an internal 2.9-kilobase region which spans the P34 gene. This supports our hypothesis that guanidine inhibits the growth of foot-and-mouth disease virus by acting on nonstructural polypeptide P34. Additional evidence was provided by RNA fingerprinting gr mutants. In two of four cases the gr mutation was associated with a change in an oligonucleotide located near the 3' end of the P34 gene; in one of these the nucleotide substitution was identified.
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PMID:Recombination and oligonucleotide analysis of guanidine-resistant foot-and-mouth disease virus mutants. 299 45

We examined the frequency-domain intensity decays of the intrinsic tryptophan fluorescence (Trp-59) from ribonuclease T1 (EC 3.1.27.3) (RNAase T1). At pH 5.5 in the native state (below 30 degrees C), the intensity decay of the single tryptophan residue is a single-exponential process. Conditions which result in protein unfolding were found to induce more complex intensity decays. At temperatures above 40 degrees C, or in the presence of guanidine hydrochloride, the intensity decays became obviously double exponential. In general, the main effect of temperature or guanidine was to induce a second subnanosecond component in the intensity decay. The increased complexity of the decays could not be explained by a unimodal distribution of decay times. These results indicate that conformational dispersion of protein structure can be one origin of the multi-exponential decays which are generally observed for protein fluorescence.
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PMID:Conformation heterogeneity in proteins as an origin of heterogeneous fluorescence decays, illustrated by native and denatured ribonuclease T1. 337 Feb 16

An attempt was made to map, in a general way, the region of the poliovirus genome that is responsible for the neurovirulent and attenuated phenotypes of different virus strains. A set of four recombinants was investigated, one described previously (E. A. Tolskaya, L. I. Romanova, M. S. Kolesnikova, and V. I. Agol, 1983, Virology 124, 121-132) and three obtained in the present work with the following genetic structure: a 5' end-adjacent segment of the genome derived from either a virulent strain (452/62 3D), or from an attenuated strain (Leon-2) of poliovirus type 3, the remaining RNA sequences being derived from either a virulent strain (Mgr), or an attenuated strain (LSc-gr3) of poliovirus type 1. The crossover points in the recombinant genomes were centrally located, somewhere between the gene(s) that determines antigenic specificity of the virus and the locus that determines resistance of virus multiplication to low doses of guanidine. The recombinant nature of the newly selected clones was definitively established by mapping RNase T1 oligonucleotides of their genome. The recombinants were characterized with respect to their ability to produce infectious progeny and synthesize viral RNA at an elevated temperature. Neurovirulence of the recombinants was assayed by intracerebral inoculation of monkeys. Irrespective of the origin of the 3' end-adjacent segment of the genome, the recombinants that inherited the 5' end-adjacent segment from the neurovirulent parent were neurovirulent, whereas the recombinants with the 5' end-adjacent segment derived from the attenuated parent were not. The results suggest that the major determinants of neurovirulence of these recombinants (and by inference, of their parental viruses) reside in the 5' end-adjacent segment of poliovirus genome, known to code for capsid proteins.
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PMID:Construction and properties of intertypic poliovirus recombinants: first approximation mapping of the major determinants of neurovirulence. 633 Sep 95

The previously reported method for the preparation of Kyn 59-RNase T1 and NFK 59-RNase T1 has been improved, and these two proteins have been obtained in high purity. Kyn 59-RNase T1, fully active for the hydrolysis of GpA and GpC, emitted a 35-fold-enhanced fluorescence of kynurenine relative to acetylnurenine amide with an emission maximum at 455 nm upon excitation at 380 nm. The polarity of the environment of Kyn 59 estimated from the emission maximum corresponded to a dielectric constant of 6. Upon excitation at 325 nm, NFK 59-RNase T1, less active than Kyn 59-RNase T1, exhibited a quenched N'-formylkynurenine fluorescence with an emission maximum at 423 nm, from which the value of 12 was obtained as the dielectric constant of the surroundings of residue 59. In both modified proteins, distinct tyrosine fluorescence appeared on excitation at 280 nm. The detection of an energy transfer from tyrosine to residue 59 suggests that the tertiary structure is very similar in Kyn 59-RNase T1 and native RNase T1. With guanidine hydrochloride, Kyn 59-RNase T1 was less stable than the native protein. Carboxymethylation at Glu 58 was shown to stabilize the active site of the modified enzyme. Based on the information collected for Kyn 59-RNase T1, the local environment and possible roles of the sole tryptophan residue in RNase T1 are discussed.
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PMID:The role of the single tryptophan residue in the structure and function of ribonuclease T1. 681 71

Alterations in flexibility of monomeric proteins induced by hydrostatic pressure in the predenaturational range (< or = 3 kbar) were probed through the decay kinetics of tryptophan phosphorescence. With apoazurin, ribonuclease T1, wild-type and V67G mutant and phosphoglycerate kinase, pressure effects on the triplet lifetime (tau) and the amplitudes of multicomponent decays emphasize that subtle changes in conformation are ubiquitous. With apoazurin the increase in tau attests to a tightening of the protein core that is enhanced at high temperature. On the contrary, tau decreases with ribonuclease T1, wild-type and mutant, and with phosphoglycerate kinase, indicating that pressure induces a greater flexibility to protein regions in proximity to the surface of the macromolecule. For phosphoglycerate kinase the decrease in tau and the parallel increase in fluorescence intensity and red-shift of the fluorescence spectrum unveil an "unfolding" like transition with midpoint pressures of 1.1 kbar at 5 degrees C and 1.6 kbar at 25 degrees C. Evidence that unfolding of the C-domain of this protein is, however, less than complete is provided by a delta G zero that is about half of that obtained by denaturation in guanidine hydrochloride and also by the ability of this structure to undergo conformational drift. In 70% glycerol, pressure effects on tau of apoazurin are attenuated while for ribonuclease T1 there is a reversal of the tendency with a pronounced increase in tau. With phosphoglycerate kinase glycerol abolishes entirely the "unfolding" transition and all hysteresis effects. A consistent picture of these findings is provided in terms of the location of the probe and of the opposing effects that pressure exerts on protein flexibility by reducing internal cavities and increasing the hydration of the polypeptide.
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PMID:Pressure effects on protein flexibility monomeric proteins. 808 48

We present a lattice Monte Carlo study to examine the effect of denaturants on the folding rates of simplified models of proteins. The two-dimensional model is made from a three-letter code mimicking the presence of hydrophobic, hydrophilic, and cysteine residues. We show that the rate of folding is maximum when the effective hydrophobic interaction epsilon H is approximately equal to the free energy gain epsilon S upon forming disulfide bonds. In the range 1 < or = epsilon H/ epsilon S < or = 3, multiple paths that connect several intermediates to the native state lead to fast folding. It is shown that at a fixed temperature and epsilon S the folding rate increases as epsilon H decreases. An approximate model is used to show that epsilon H should decrease as a function of the concentration of denaturants such as urea or guanidine hydrochloride. Our simulation results, in conjunction with this model, are used to show that increasing the concentration of denaturants can lead to an increase in folding rates. This occurs because denaturants can destabilize the intermediates without significantly altering the energy of the native conformation. Our findings are compared with experiments on the effects of denaturants on the refolding of bovine pancreatic trypsin inhibitor and ribonuclease T1. We also argue that the phenomenon of denaturant-enhanced folding of proteins should be general.
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PMID:Denaturants can accelerate folding rates in a class of globular proteins. 888 Sep 6

The rate-limiting step during the refolding of S54G/P55N ribonuclease T1 is determined by the slow trans-->cis prolyl isomerisation of Pro39. We investigated the refolding of this variant by one-dimensional (1D) and two-dimensional (2D) real-time NMR spectroscopy, initiated by a tenfold dilution from 6 M guanidine hydrochloride at 10 degreesC. Two intermediates could be resolved with the 1D approach. The minor intermediate, which is only present early during refolding, is largely unfolded. The major intermediate, with an incorrect trans Pro39 peptide bond, is highly structured with 33 amide protons showing native chemical shifts and native NOE patterns. They could be assigned in a real-time 2D-NOESY (nuclear Overhauser enhancement spectroscopy) by using a new assignment strategy to generate positive and negative signal intensities for native and non-native NOE cross-peaks, respectively. Surprisingly, amide protons with non-native environments are located not only close to Tyr38-Pro39, but are spread throughout the entire protein, including the C-terminal part of the alpha-helix, beta-strands 3 and 4 and several loop regions. Native secondary and tertiary structure was found for the major intermediate in the N-terminal beta-strands 1 and 2 and the C terminus (connected by the disulfide bonds), the N-terminal part of the alpha-helix, and the loops between beta-strands 4/5 and 5/6. Implications of these native and non-native structure elements of the intermediate for the refolding of S54G/P55N ribonuclease T1 and for cis/trans isomerizations are discussed.
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PMID:A protein folding intermediate of ribonuclease T1 characterized at high resolution by 1D and 2D real-time NMR spectroscopy. 987 47

This article probes the denatured state ensemble of ribonuclease Sa (RNase Sa) using fluorescence. To interpret the results obtained with RNase Sa, it is essential that we gain a better understanding of the fluorescence properties of tryptophan (Trp) in peptides. We describe studies of N-acetyl-L-tryptophanamide (NATA), a tripeptide: AWA, and six pentapeptides: AAWAA, WVSGT, GYWHE, HEWTV, EAWQE, and DYWTG. The latter five peptides have the same sequence as those surrounding the Trp residues studied in RNase Sa. The fluorescence emission spectra, the fluorescence lifetimes, and the fluorescence quenching by acrylamide and iodide were measured in concentrated solutions of urea and guanidine hydrochloride. Excited-state electron transfer from the indole ring of Trp to the carbonyl groups of peptide bonds is thought to be the most important mechanism for intramolecular quenching of Trp fluorescence. We find the maximum fluorescence intensities vary from 49,000 for NATA with two carbonyls, to 24,400 for AWA with four carbonyls, to 28,500 for AAWAA with six carbonyls. This suggests that the four carbonyls of AWA are better able to quench Trp fluorescence than the six carbonyls of AAWAA, and this must reflect a difference in the conformations of the peptides. For the pentapeptides, EAWQE has a fluorescence intensity that is more than 50% greater than DYWTG, showing that the amino acid sequence influences the fluorescence intensity either directly through side-chain quenching and/or indirectly through an influence on the conformational ensemble of the peptides. Our results show that peptides are generally better models for the Trp residues in proteins than NATA. Finally, our results emphasize that we have much to learn about Trp fluorescence even in simple compounds.
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PMID:Peptide sequence and conformation strongly influence tryptophan fluorescence. 1806 77


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