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
Query: EC:3.1.27.3 (
RNase T1
)
1,228
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In wild-type
ribonuclease T1
the peptide bond between Tyr38 and Pro39 is in the cis conformation. When Pro39 is replaced by an
alanine
this cis conformation is retained, and a non-prolyl cis Tyr38-Ala39 peptide bond is generated. We employed a stopped-flow double-mixing technique to investigate the kinetics of the cis-->trans isomerization of this peptide bond in the unfolding and the trans-->cis isomerization in the refolding of Pro39Ala-
ribonuclease T1
. In 6.0 M GdmCl (pH 1.6) and 25 degrees C the protein unfolds rapidly with a time constant of 20 ms, followed by Tyr38-Ala39 cis-->trans isomerization. This reaction shows a time constant of 730 ms and is about 60-fold faster than the isomerization of the Tyr38-Pro39 bond in the wild-type protein. Unfolded molecules with the Tyr38-Ala39 bond still in the native-like cis conformation accumulate transiently for a short time after unfolding is initiated, and they can refold very rapidly to the native state with a time constant of 290 ms (in 1.0 M GdmCl, pH 4.6, 25 degrees C). After more than three seconds of unfolding virtually all protein molecules contain an incorrect trans Tyr38-Ala39 bond and refolding is decelerated approximately 1000-fold, because Tyr38-Ala39 trans-->cis re-isomerization is very slow and, with its time constant of 480 s, determines the overall rate of refolding. Due to the coupling of the cis-trans equilibrium with protein folding it was possible to measure the kinetic parameters of the isomerization of a non-prolyl peptide bond in a protein. Previously this could not be accomplished, because the trans isomer is strongly preferred for unsubstituted peptide bonds in oligopeptides under virtually all conditions. Our data indicate that the kinetics of Tyr38-Pro39 and of Tyr38-Ala39 isomerization differ predominantly in the rate of the cis-->trans, rather than of the trans-->cis reaction. The rate of the trans-->cis reaction is, however, measured during refolding and may be influenced by the formation of ordered protein structure.
...
PMID:Non-prolyl cis-trans peptide bond isomerization as a rate-determining step in protein unfolding and refolding. 782 21
To elucidate the functional role of some residues in the active site of
binase
, the extracellular ribonuclease of Bacillus intermedius, we used site-directed mutagenesis. On cleavage of various substrates the catalytic activity of
binase
mutant His101 Glu is 2.0-2.7% of that for the native enzyme. The decrease in activity is determined mainly by the decrease in molecular rate constant kcat, with almost unchanged affinity of the enzyme for the substrate, characterized by KM. This is the expected result if His101 acts as an general acid, donating a proton to the leaving group on cleavage of a phosphodiester bond. The replacement of Lys26 by
Ala
causes a reduction in the enzyme activity to 13-33%, depending on the substrate. The activity decreases are due to changes in both kcat and KM for poly(A) and poly(A) but in kcat alone for GpA. In the latter case the effect is far less than that seen in the homologous mutation in the closely related enzyme, barnase.
...
PMID:Mutational analysis of the active site of RNase of Bacillus intermedius (BINASE). 795 45
The cis conformation of the 38-39 peptide bond of
ribonuclease T1
is retained after the replacement of cis Pro39 by an
alanine
residue. This conformation is demonstrated by the presence of a NOESY cross-peak in the NMR spectrum between the C alpha protons of Tyr38 and Ala39 in the Pro39-->
Ala
variant. The presence of this non-prolyl cis peptide bond explains the retention of the catalytic activity, the strong decrease in stability and the changes in the folding mechanism that were observed after the Pro39-->
Ala
mutation in
ribonuclease T1
. We suggest that a cis peptide bond is retained in a protein after the substitution of a cis proline at positions, where a trans bond would destabilize the protein more strongly than a non-prolyl peptide bond in the energetically unfavourable cis conformation.
...
PMID:Generation of a non-prolyl cis peptide bond in ribonuclease T1. 803 56
Two mutants of
ribonuclease T1
(RNaseT1), [59-tyrosine]
ribonuclease T1
(W59Y) and [45-tryptophan,59-tyrosine]
ribonuclease T1
(Y45W/W59Y) possess between 150% and 190% wild-type activity. They have been crystallised as complexes of the inhibitor 2'-guanylic acid and analysed by X-ray diffraction at resolutions of 0.23 nm and 0.24 nm, respectively. The space group for both is monoclinic, P2(1), with two molecules/asymmetric unit, W59Y: a = 4.934 nm, b = 4.820 nm, c = 4.025 nm, beta = 90.29 degrees. Y45W/W59Y: a = 4.915 nm, b = 4.815 nm, c = 4.015 nm, beta = 90.35 degrees. Compared to wild-type RNaseT1 in complex with 2'-guanylic acid (2'GMP) both mutant inhibitor complexes indicate that the replacement of Trp59 by Tyr leads to a 0.04-nm inward shift of the single alpha-helix and to significant differences in the active-site geometry, inhibitor conformation and inhibitor binding. Calorimetric studies of a range of mutants [24-tryptophan]
ribonuclease T1
(Y24W), [42-tryptophan]
ribonuclease T1
(Y42W), [45-tryptophan]
ribonuclease T1
(Y45W), [92-
alanine
]
ribonuclease T1
(H92A) and [92-threonine]
ribonuclease T1
(H92T) with and without the further mutation Trp59-->Tyr showed that mutant proteins for which Trp59 is replaced by Tyr exhibit slightly decreased thermal stability.
...
PMID:X-ray crystallographic and calorimetric studies of the effects of the mutation Trp59-->Tyr in ribonuclease T1. 812 11
We report on the functional cooperativity of the primary site and the subsite of
ribonuclease T1
(
RNase T1
;
EC 3.1.27.3
). The kinetic properties of the single Tyr-38-Phe and Asn-98-
Ala
mutants have been compared with those of the corresponding double mutant. The Tyr-38-Phe mutation has been used to probe enzyme-substrate interactions at the primary site; the Asn-98-
Ala
mutation monitors subsite interactions. In addition to the dinucleoside phosphate substrate GpC, we measured the kinetics for GpMe, a synthetic substrate in which the leaving nucleoside cytosine has been replaced by methanol. All data were combined in a triple mutant box to analyze the interplay between Tyr-38, Asn-98, and the leaving group. The free energy barriers to kcat, introduced by the single Tyr-38-Phe and Asn-98-
Ala
mutations are not additive in the corresponding double mutant. The energetic coupling between both mutations is independent of the binding of the leaving cytosine at the subsite. We conclude that the coupling of the Tyr-38-Phe and Asn-98-
Ala
mutations arises through distortion or reorientation of the 3'-guanylic acid moiety bound at the primary site. The experimental data indicate that the enzyme-substrate interactions beyond the scissile phosphodiester bond contribute to catalysis through the formation of new or improved contacts in going from ground state to transition state, which are functionally independent of primary site interactions.
...
PMID:Investigation of the functional interplay between the primary site and the subsite of RNase T1: kinetic analysis of single and multiple mutants for modified substrates. 820 24
The refolding of
ribonuclease T1
involves two major slow processes that exhibit properties of prolyl isomerization reactions. A comparison of the wild-type protein and a designed variant where the cis Ser54-Pro55 bond was replaced by a Gly54-Asn55 bond indicated that the faster of these reactions is the isomerization of Pro55. Here we report the replacement of the other cis proline of
ribonuclease T1
at position 39 by
alanine
. The Pro39Ala variant is similar to the wild-type protein in secondary and tertiary structure, and the enzymatic activity towards RNA and a dinucleotide substrate remains almost unchanged. The fluorescence emission of the single Trp59 is lowered by the Pro39Ala substitution, probably because Trp59 is in close contact to Pro39 in wild-type
ribonuclease T1
. Unlike the substitution of cis Pro55, the Pro39Ala mutation is strongly destabilizing and reduces the Gibbs free energy of the folded protein by about 20 kJ/mol. Pro39 is buried in native
RNase T1
and located near the active site. The observed destabilization could originate from the presence of a cis alanyl bond in the Pro39Ala variant or from a local distortion caused by the incorporation of a trans alanyl peptide bond in the interior of the protein. In the refolding kinetics the replacement of Pro39 leads to a disappearance of the fast-refolding species. Refolding still involves two consecutive slow steps. The first and faster step could be the isomerization of the remaining cis Pro55. The second, very slow step is a novel reaction that appears to have no counterpart in the refolding of the wild-type protein. All mutant molecules must undergo this reaction before reaching the native state. These major changes in the folding kinetics strongly indicate that cis-Pro39 is indeed of major importance for the folding of the wild-type protein. They indicate, moreover, that some new feature of protein folding kinetics is observed in these studies of the Pro39Ala variant.
...
PMID:Stability and folding kinetics of ribonuclease T1 are strongly altered by the replacement of cis-proline 39 with alanine. 851 59
The replacement of cis proline 39 of
ribonuclease T1
by an
alanine
residue leads to a decrease in stability by about 20 kJ/mol and to major changes in the folding kinetics that are not easily explained by the proline model for protein folding. In particular, a novel very slow reaction is observed in the refolding of the Pro39Ala variant. Here the unfolding and refolding kinetics of this protein are further investigated. We show that the very slow reaction is not a prolyl isomerization. It is not created by a slow isomerization of the unfolded protein, nor is it catalyzed by prolyl isomerase, and all molecules have to undergo this reaction during refolding. Most of the unfolded Pro39Ala molecules contain an incorrect trans isomer at the remaining cis Pro55. They use a sequential pathway for refolding, in which trans to cis isomerization at Pro55 precedes the very slow reaction. The refolding of the minor fraction of unfolded Pro39Ala molecules with a correct cis isomer at proline 55 is a single first-order reaction that is limited in rate by the very slow step. The folding mechanism of wild-type
ribonuclease T1
cannot be used to explain these results and independent mechanisms are proposed to model the unfolding and refolding of the Pro39Ala variant. The molecular interpretation of the changes in the folding mechanism is tied to the question, as to whether the cis character of the peptide bond at position 38-39 is maintained after the substitution of Pro39 by
alanine
. A possible explanation could be that the novel very slow folding reaction involves the trans to cis isomerization of the Tyr38-Ala39 bond. Such a reaction is probably slow, since the activation energy is high and since tight coupling with the formation of structure is required to stabilize the cis form of a non-prolyl peptide bond. Alternatively, the strong decrease in folding rate could be correlated with the general destabilization of
ribonuclease T1
by the Pro39Ala mutation.
...
PMID:Kinetic models for unfolding and refolding of ribonuclease T1 with substitution of cis-proline 39 by alanine. 851 60
Ribonuclease T1 (
RNase T1
) is a small, globular protein of 104 amino acids for which extensive thermodynamic and structural information is known. To assess the specific influence of variations in amino acid sequence on the mechanism for protein folding, circularly permuted variants of
RNase T1
were constructed and characterized in terms of catalytic activity and thermodynamic stability. The disulfide bond connecting Cys-2 and Cys-10 was removed by mutation of these residues to
alanine
(C2, 10A) to avoid potential steric problems imposed by the circular permutations. The original amino-terminus and carboxyl-terminus of the mutant (C2, 10A) were subsequently joined with a tripeptide linker to accommodate a reverse turn and new termini were introduced throughout the primary sequence in regions of solvent-exposed loops at Ser-35 (cp35S1), Asp-49 (cp49D1), Gly-70 (cp70G1), and Ser-96 (cp96S1). These circularly permuted
RNase T1
mutants retained 35-100% of the original catalytic activity for the hydrolysis of guanylyl(3'-->5')cytidine, suggesting that the overall tertiary fold of these mutants is very similar to that of wild-type protein. Chemical denaturation curves indicated thermodynamic stabilities at pH 5.0 of 5.7, 2.9, 2.6, and 4.6 kcal/mol for cp35S1, cp49D1, cp70G1, and cp96S1, respectively, compared to a value of 10.1 kcal/mol for wild-type
RNase T1
and 6.4 kcal/mol for (C2, 10A) T1. A fifth set of circularly permuted variants was attempted with new termini positioned in a tight beta-turn between Glu-82 and Gln-85. New termini were inserted at Asn-83 (cp83N1), Asn-84 (cp84N1), and Gln-85 (cp85Q1). No detectable amount of protein was ever produced for any of the mutations in this region, suggesting that this turn may be critical for the proper folding and/or thermodynamic stability of
RNase T1
.
...
PMID:Are turns required for the folding of ribonuclease T1? 874 97
The function of the conserved Phe 100 residue of
RNase T1
(
EC 3.1.27.3
) has been investigated by site-directed mutagenesis and X-ray crystallography. Replacement of Phe 100 by
alanine
results in a mutant enzyme with kcat reduced 75-fold and a small increase in Km for the dinucleoside phosphate substrate GpC. The Phe 100
Ala
substitution has similar effects on the turnover rates of GpC and its minimal analogue GpOMe, in which the leaving cytidine is replaced by methanol. The contribution to catalysis is independent of the nature of the leaving group, indicating that Phe 100 belongs to the primary site. The contribution of Phe 100 to catalysis may result from a direct van der Waals contact between its aromatic ring and the phosphate moiety of the substrate. Phe 100 may also contribute to the positioning of the pentacovalent phosphorus of the transition state, relative to other catalytic residues. If compared to the corresponding wild-type data, the structural implications of the mutation in the present crystal structure of Phe 100
Ala
RNase T1
complexed with the specific inhibitor 2'-GMP are restricted to the active site. Repositioning of 2'-GMP, caused by the Phe 100
Ala
mutation, generates new or improved contacts of the phosphate moiety with Arg 77 and His 92. In contrast, interactions with the Glu 58 carboxylate appear to be weakened. The effects of the His 92 Gln and Phe 100
Ala
mutations on GpC turnover are additive in the corresponding double mutant, indicating that the contribution of Phe 100 to catalysis is independent of the catalytic acid His 92. The present results lead to the conclusion that apolar residues may contribute considerably to catalyze conversions of charged molecules to charged products, involving even more polar transition states.
...
PMID:A catalytic function for the structurally conserved residue Phe 100 of ribonuclease T1. 884 43
alpha-Helical secondary structure occurs widely in globular proteins and its formation is a key step in their folding. As a consequence, understanding the energetics of helix formation is crucial to understanding protein folding and stability. We have measured the helix propensities of the nonpolar amino acids for an alpha-helix in an intact protein,
ribonuclease T1
, and for a 17-residue peptide with a sequence identical to that of the alpha-helix in the protein. The helix propensities are in excellent agreement. This shows that when compared in the same sequence context, the helix propensities of the nonpolar amino acids are identical in helical peptides and intact proteins, and that conclusions based on studies of the helix-to-coil transitions of peptides may, in favorable cases, be directly applicable to proteins. Our helix propensities based on
ribonuclease T1
are in good agreement with those from similar studies of barnase and T4 lysozyme. In contrast, our helix propensities differ substantially from those derived from studies of
alanine
-stabilized or salt bridge-stabilized model alpha-helical peptides.
...
PMID:A direct comparison of helix propensity in proteins and peptides. 909 98
<< Previous
1
2
3
4
5
Next >>
