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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 X-ray crystal structure of a complex between
ribonuclease T1
and guanylyl(3'-6')-6'-deoxyhomouridine (GpcU) has been determined at 2. 0 A resolution. This ligand is an isosteric analogue of the minimal RNA substrate, guanylyl(3'-5')uridine (GpU), where a methylene is substituted for the uridine 5'-oxygen atom. Two protein molecules are part of the asymmetric unit and both have a GpcU bound at the active site in the same manner. The protein-protein interface reveals an extended aromatic stack involving both guanines and three enzyme phenolic groups. A third GpcU has its guanine moiety stacked on His92 at the active site on enzyme molecule A and interacts with GpcU on molecule B in a neighboring unit via
hydrogen
bonding between uridine ribose 2'- and 3'-OH groups. None of the uridine moieties of the three GpcU molecules in the asymmetric unit interacts directly with the protein. GpcU-active-site interactions involve extensive
hydrogen
bonding of the guanine moiety at the primary recognition site and of the guanosine 2'-hydroxyl group with His40 and Glu58. On the other hand, the phosphonate group is weakly bound only by a single
hydrogen
bond with Tyr38, unlike ligand phosphate groups of other substrate analogues and 3'-GMP, which
hydrogen
-bonded with three additional active-site residues.
Hydrogen
bonding of the guanylyl 2'-OH group and the phosphonate moiety is essentially the same as that recently observed for a novel structure of a
RNase T1
-3'-GMP complex obtained immediately after in situ hydrolysis of exo-(Sp)-guanosine 2',3'-cyclophosphorothioate [Zegers et al. (1998) Nature Struct. Biol. 5, 280-283]. It is likely that GpcU at the active site represents a nonproductive binding mode for GpU [Steyaert, J., and Engleborghs (1995) Eur. J. Biochem. 233, 140-144]. The results suggest that the active site of
ribonuclease T1
is adapted for optimal tight binding of both the guanylyl 2'-OH and phosphate groups (of GpU) only in the transition state for catalytic transesterification, which is stabilized by adjacent binding of the leaving nucleoside (U) group.
...
PMID:Three-dimensional structure of ribonuclease T1 complexed with an isosteric phosphonate substrate analogue of GpU: alternate substrate binding modes and catalysis. 1002 39
The reoccurrence of water molecules in crystal structures of
RNase T1
was investigated. Five waters were found to be invariant in
RNase T1
as well as in six other related fungal RNases. The structural, dynamical, and functional characteristics of one of these conserved hydration sites (WAT1) were analyzed by protein engineering, X-ray crystallography, and (17)O and 2H nuclear magnetic relaxation dispersion (NMRD). The position of WAT1 and its surrounding
hydrogen
bond network are unaffected by deletions of two neighboring side chains. In the mutant Thr93Gln, the Gln93N epsilon2 nitrogen replaces WAT1 and participates in a similar
hydrogen
bond network involving Cys6, Asn9, Asp76, and Thr91. The ability of WAT1 to form four
hydrogen
bonds may explain why evolution has preserved a water molecule, rather than a side-chain atom, at the center of this intricate
hydrogen
bond network. Comparison of the (17)O NMRD profiles from wild-type and Thr93Gln
RNase T1
yield a mean residence time of 7 ns at 27 degrees C and an orientational order parameter of 0.45. The effects of mutations around WAT1 on the kinetic parameters of
RNase T1
are small but significant and probably relate to the dynamics of the active site.
...
PMID:Dissection of the structural and functional role of a conserved hydration site in RNase T1. 1021 18
It is difficult to increase protein stability by adding
hydrogen
bonds or burying nonpolar surface. The results described here show that reversing the charge on a side chain on the surface of a protein is a useful way of increasing stability. Ribonuclease T1 is an acidic protein with a pI approximately 3.5 and a net charge of approximately -6 at pH 7. The side chain of Asp49 is hyperexposed, not
hydrogen
bonded, and 8 A from the nearest charged group. The stability of Asp49Ala is 0.5 kcal/mol greater than wild-type at pH 7 and 0.4 kcal/mol less at pH 2.5. The stability of Asp49His is 1.1 kcal/mol greater than wild-type at pH 6, where the histidine 49 side chain (pKa = 7.2) is positively charged. Similar results were obtained with ribonuclease Sa where Asp25Lys is 0.9 kcal/mol and Glu74Lys is 1.1 kcal/mol more stable than the wild-type enzyme. These results suggest that protein stability can be increased by improving the coulombic interactions among charged groups on the protein surface. In addition, the stability of
RNase T1
decreases as more hydrophobic aromatic residues are substituted for Ala49, indicating a reverse hydrophobic effect.
...
PMID:Increasing protein stability by altering long-range coulombic interactions. 1049 85
The side-chain carboxyl of Asp 76 in
ribonuclease T1
(
RNase T1
) is buried, charged, non-ion-paired, and forms three good intramolecular
hydrogen
bonds (2.63, 2.69, and 2.89 A) and a 2.66 A
hydrogen
bond to a buried, conserved water molecule. When Asp 76 was replaced by Asn, Ser, and Ala, the conformational stability of the protein decreased by 3.1, 3.2, and 3.7 kcal/mol, respectively. The stability was measured as a function of pH for wild-type
RNase T1
and the D76N mutant and showed that the pH dependence below pH 3 was almost entirely due to Asp 76. The pK of Asp 76 is 0.5 in the native state and 3.7 in the denatured state. Thus, the
hydrogen
bonding of the carboxyl group of Asp 76 contributes more than half of the net stability of
RNase T1
at pH 7. In addition, the charged carboxyl of Asp 76 stabilizes structure in the denatured states of
RNase T1
that is not present in D76N, D76S, and D76A.
...
PMID:Buried, charged, non-ion-paired aspartic acid 76 contributes favorably to the conformational stability of ribonuclease T1. 1052 13
Hydrogen
-exchange rates were measured for
RNase T1
and three variants with Ala --> Gly substitutions at a solvent-exposed (residue 21) and a buried (residue 23) position in the helix: A21G, G23A, and A21G + G23A. These results were used to measure the stabilities of the proteins. The
hydrogen
-exchange stabilities (DeltaG(HX)) for the most stable residues in each variant agree with the equilibrium conformational stability measured by urea denaturation (DeltaG(U)), if the effects of D(2)O and proline isomerization are included [Huyghues-Despointes, B. M. P., Scholtz, J. M., and Pace, C. N. (1999) Nat. Struct. Biol. 6, 210-212]. These residues also show similar changes in DeltaG(HX) upon Ala --> Gly mutations (DeltaDeltaG(HX)) as compared to equilibrium measurements (DeltaDeltaG(U)), indicating that the most stable residues are exchanging from the globally unfolded ensemble. Alanine is stabilizing compared to glycine by 1 kcal/mol at a solvent-exposed site 21 as seen by other methods for the
RNase T1
protein and peptide helix [Myers, J. K., Pace, C. N., and Scholtz, J. M. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 3833-2837], while it is destabilizing at the buried site 23 by the same amount. For the A21G variant, only local NMR chemical shift perturbations are observed compared to
RNase T1
. For the G23A variant, large chemical shift changes are seen throughout the sequence, although X-ray crystal structures of the variant and
RNase T1
are nearly superimposable. Ala --> Gly mutations in the helix of
RNase T1
at both helical positions alter the native-state
hydrogen
-exchange stabilities of residues throughout the sequence.
...
PMID:Hydrogen-exchange stabilities of RNase T1 and variants with buried and solvent-exposed Ala --> Gly mutations in the helix. 1060 Jan 9
The experimental NMR data for the individual titratable groups in
ribonuclease T1
presented in the preceding paper were analysed by means of a continuum dielectric model. The role of two factors, the alteration of
hydrogen
loci on the ionizable groups and the conformational flexibility, were analysed. It was suggested that the position of the titratable
hydrogen
is essential mainly for strongly interacting groups. For groups which are accessible to the solvent and whose ionization is not coupled with the ionization of neighbouring groups, this factor can be neglected. The influence of the conformational flexibility on the electrostatic interactions becomes apparent for the environment of K25. For some strongly interacting groups, non-sigmoidal ionization curves were calculated. On this basis the pH dependence of the NMR chemical shift of the 13Cepsilon2 resonance of H27, whose ionization is coupled with E82, was reproduced.
...
PMID:Ionization properties of titratable groups in ribonuclease T1. II. Electrostatic analysis. 1150 39
The aim of this study was to gain a better understanding of the contribution of
hydrogen
bonds by tyrosine -OH groups to protein stability. The amino acid sequences of RNases Sa and Sa3 are 69 % identical and each contains eight Tyr residues with seven at equivalent structural positions. We have measured the stability of the 16 tyrosine to phenylalanine mutants. For two equivalent mutants, the stability increases by 0.3 kcal/mol (
RNase Sa
Y30F) and 0.5 kcal/mol (RNase Sa3 Y33F) (1 kcal=4.184 kJ). For all of the other mutants, the stability decreases with the greatest decrease being 3.6 kcal/mol for
RNase Sa
Y52F. Seven of the 16 tyrosine residues form intramolecular
hydrogen
bonds and the average decrease in stability for these is 2.0(+/-1.0) kcal/mol. For the nine tyrosine residues that do not form intramolecular
hydrogen
bonds, the average decrease in stability is 0.4(+/-0.6) kcal/mol. Thus, most tyrosine -OH groups contribute favorably to protein stability even if they do not form intramolecular
hydrogen
bonds. Generally, the stability changes for equivalent positions in the two proteins are remarkably similar. Crystal structures were determined for two of the tyrosine to phenylalanine mutants of
RNase Sa
: Y80F (1.2 A), and Y86F (1.7 A). The structures are very similar to that of wild-type
RNase Sa
, and the
hydrogen
bonding partners of the tyrosine residues always form intermolecular
hydrogen
bonds to water in the mutants. These results provide further evidence that the
hydrogen
bonding and van der Waals interactions of polar groups in the tightly packed interior of folded proteins are more favorable than similar interactions with water in the unfolded protein, and that polar group burial makes a substantial contribution to protein stability.
...
PMID:Tyrosine hydrogen bonds make a large contribution to protein stability. 1155 95
The pseudomolecule approach to the structure of globular proteins in which a small number of water molecules are incorporated into the "molecule" is tested again by comparing the ribbon of
hydrogen
bonds in two proteins,
ribonuclease F1
and T1. These two molecules are 59% homologous and have the same backbone conformation both globally and locally. The two ribbons of
hydrogen
bonds that cover the whole of the backbone are conserved with an accuracy of some 95% providing that allowance is made for the intrusion into one of the pair of such extra factors as the presence of adducts or metal ions, the insertions and the absence of a few water molecules from one of the x-ray data sets. Without these corrections, the conservation of the ribbon is some 85%. There are 35 conserved
hydrogen
-bonding residues, nearly all of which show many unions to the backbone or interactions with the active site. There are 36 point mutations that involve one or two
hydrogen
-bonding side chains and nearly all of these have either none or one
hydrogen
bond to the backbone. These are minor contributors to the ribbon of
hydrogen
bonds. Of the 71 residues involved in these two categories, all but six fit into the pseudomolecular picture of the structure of globular proteins. The remaining 30 residues almost all contain conserved hydrocarbon side chains that may have a second order effect on the structure through their space filling effects.
...
PMID:The pseudomolecule method and the structure of globular proteins. II. The example of ribonuclease F1 and T1. 1159 75
Coulomb's law and a finite difference Poisson-Boltzmann based analysis are used to predict the pK values for 15 ionizable side chains (6 Asp, 6 Glu and 3 His) in
ribonuclease T1
. These predicted values are compared to the measured pK values to gain insight into the most important factors that influence the pK values of the ionizable groups in proteins. Charge-charge interactions are clearly the most important factor that determines the pK values of most ionizable groups in
ribonuclease T1
. However, pK values can be shifted by several pK units by the Born self energy associated with burying ionizable groups and by favorable intramolecular
hydrogen
bonding.
...
PMID:Charge-charge interactions are the primary determinants of the pK values of the ionizable groups in Ribonuclease T1. 1248 2
The pK values of the titratable groups in ribonuclease Sa (
RNase Sa
) (pI=3.5), and a charge-reversed variant with five carboxyl to lysine substitutions, 5K
RNase Sa
(pI=10.2), have been determined by NMR at 20 degrees C in 0.1M NaCl. In
RNase Sa
, 18 pK values and in 5K, 11 pK values were measured. The carboxyl group of Asp33, which is buried and forms three intramolecular
hydrogen
bonds in
RNase Sa
, has the lowest pK (2.4), whereas Asp79, which is also buried but does not form
hydrogen
bonds, has the most elevated pK (7.4). These results highlight the importance of desolvation and charge-dipole interactions in perturbing pK values of buried groups. Alkaline titration revealed that the terminal amine of
RNase Sa
and all eight tyrosine residues have significantly increased pK values relative to model compounds.A primary objective in this study was to investigate the influence of charge-charge interactions on the pK values by comparing results from
RNase Sa
with those from the 5K variant. The solution structures of the two proteins are very similar as revealed by NMR and other spectroscopic data, with only small changes at the N terminus and in the alpha-helix. Consequently, the ionizable groups will have similar environments in the two variants and desolvation and charge-dipole interactions will have comparable effects on the pK values of both. Their pK differences, therefore, are expected to be chiefly due to the different charge-charge interactions. As anticipated from its higher net charge, all measured pK values in 5K RNase are lowered relative to wild-type
RNase Sa
, with the largest decrease being 2.2 pH units for Glu14. The pK differences (pK(Sa)-pK(5K)) calculated using a simple model based on Coulomb's Law and a dielectric constant of 45 agree well with the experimental values. This demonstrates that the pK differences between wild-type and 5K
RNase Sa
are mainly due to changes in the electrostatic interactions between the ionizable groups. pK values calculated using Coulomb's Law also showed a good correlation (R=0.83) with experimental values. The more complex model based on a finite-difference solution to the Poisson-Boltzmann equation, which considers desolvation and charge-dipole interactions in addition to charge-charge interactions, was also used to calculate pK values. Surprisingly, these values are more poorly correlated (R=0.65) with the values from experiment. Taken together, the results are evidence that charge-charge interactions are the chief perturbant of the pK values of ionizable groups on the protein surface, which is where the majority of the ionizable groups are positioned in proteins.
...
PMID:Charge-charge interactions are key determinants of the pK values of ionizable groups in ribonuclease Sa (pI=3.5) and a basic variant (pI=10.2). 1252 9
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