EC:3.1.27.3 - FACTA Search

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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)

1. Ribonuclease T1 [EC 3.1.4.8] was inactivated by reaction with tosylglycolate (carboxymethyl rho-toluenesulfonate). At pH 5.5 and 8.0, alkylation of the gamma-carboxyl group of glutamic acid-58 appeared to be the predominant reaction and the major cause of inactivation by tosylglycolate, as in the case of the iodoacetate reaction, although the rate of inactivation was slower than that by iodoacetate. At pH 8.0, histidine residues were also alkylated to some extent. 2. The maximal rate of inactivation was observed at around pH 5.5 and the pH dependence of the rate of inactivation suggested the implication of two groups in the reaction, with apparent pKa values of about 3-4 (possibly histidine residue(s)). 3. In the presence of substrate analogs, ribonuclease T1 was markedly protected from inactivation by tosylglycolate at pH 5.5. The extent of protection corresponded to the binding strength of the substrate analog, except for guanosine. Ribonuclease T1 was much less protected from inactivation by guanosine than by 3'-AMP or 3'-CMP, which has a lower binding strength toward ribonuclease T1. This may indicate that glutamic acid-58 is situated in the catalytic site, at which the phosphate moiety of these nucleotides directly interacts. 4. Enzyme which had been extensively inactivated with tosylglycolate at pH 5.5 scarcely reacted with iodoacetate at pH 5.5, suggesting that these reagents react at the same site, i.e. glutamic acid-58. On the other hand, enzyme which had been inactivated almost completely with tosylglycolate at pH 8.0 still reacted with iodoacetate to some extent at pH 8.0, and the modes of reaction of tosylglycolate and iodoacetate toward ribonuclease T1 appeared to be somewhat different.
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PMID:The structure and function of ribonuclease T1. XX. Specific inactivation of ribonuclease T1 by reaction with tosylglycolate. 1 19

1. When ribonuclease T1 [EC 3.1.4.8] (0.125% solution) was treated with a 760-fold molar excess of iodoacetamide at pH 8.0 and 37 degrees, about 90% of the original activity was lost in 24 hr. The half-life of the activity was about 8 hr. The binding ability for 3'-GMP was lost simultaneously. Changes were detected only in histidine and the amino-terminal alanine residues upon amino acid analyses of the inactivated protein and its chymotryptic peptides. The inactivation occurred almost in parallel with the loss of two histidine residues in the enzyme. The pH dependences of the rate of inactivation and that of loss of histidine residues were similar and indicated the implication of a histidine residue or residues with pKa 7.5 to 8 in this reaction. 3'-GMP and guanosine showed some protective effect against loss of activity and of histidine residues. The reactivity of histidine residues was also reduced by prior modification of glutamic acid-58 with iodoacetate, of lysine-41 with maleic or cis-aconitic anhydride or 2,4,6-trinitrobenzenesulfonate or of arginine-77 with ninhydrin. 2. Analyses of the chymotryptic peptides from oxidized samples of the iodoacetamide-inactivated enzyme showed that histidine-92 and histidine-40 reacted with iodoacetamide most rapidly and at similar rates, whereas histidine-27 was least reactive. Alkylation of histidine-92 was markedly slowed down when the Glu58-carboxymethylated enzyme was treated with iodoacetamide. On the other hand, alkylation of histidine-40 was slowed down most in the presence of 3'-GMP. These results suggest that histidine-92 and histidine-40 are involved in the catalytic action, probably forming part of the catalytic site and part of the binding site, respectively, and that histidine-27 is partially buried in the enzyme molecule or interacts strongly with some other residue, thus becoming relatively unreactive.
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PMID:The structure and function of ribonuclease T1. XXI. Modification of histidine residues in ribonuclease T1 with iodoacetamide. 1 20

In order to obtain information on the nature of the amino acid residues involved in the activity of ribonuclease U1 [EC 3.1.4.8], various chemical modifications of the enzyme were carried out. RNase U1 was inactivated by reaction with iodoacetate at pH 5.5 with concomitant incorporation of 1 carboxymethyl group per molecule of the enzyme. The residue specifically modified by iodoacetate was identified as one of the glutamic acid residues, as in the case of RNase T1. The enzyme was also inactivated extensively by reaction with iodoacetamide at pH 8.0 with the loss of about one residue each of histidine and lysine. When RNase U1 was treated with a large excess of phenylglyoxal, the enzymatic activity and binding ability toward 3'-GMP were lost, with simultaneous modification of about 1 residue of arginine. The reaction of citraconic anhydride with RNase U1 led to the loss of enzymatic activity and modification of about 1 residue of lysine. The inactivated enzyme, however, retained binding ability toward 3'-GMP. These results indicate that there are marked similarities in the active sites of RNases T1 and U1.
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PMID:Chemical modifications of ribonuclease U1. 1 50

Low-pH-induced difference spectra for ribonuclease T1, which were determined using a reference solution at pH 6, consisted of a shorter wavelength component from 270 to 285 nm that relfected an ionization having a pKa of 3.54 and a longer wavelength component above 285 nm that reflected an ionization having a pKa of 4.29. The temperature dependence of the pKa value for data at 300 nm is consistent with its representing the dissociation of a carboxyl group. In addition, the pKa determined at this wavelength significantly decreased at lower ionic strength. Similar experiments which were conducted using catalytically inactive gamma-carboxymethyl-Glu-58-ribonuclease T1 gave difference spectra having only the shorter wavelength component and were characterized by a single pKa of 3.53. It is concluded that the longer wavelength component of the difference spectra is due to the ionization of Glu-58. The pKa determined for this residue in the present study agrees with one found previously from kinetic studies which supports a role for Glu-58 in catalysis. Furthermore, the results suggest a model for the interaction of Glu-58 with histidine and tryptophan residues at the active site.
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PMID:Spectrophotometric titration of a single carboxyl group at the active site of ribonuclease T1. 2 Sep 34

A 70-residue analog of RNase S-protein was synthesized by the solid phase method. It was obtained by omitting the NH2 terminus from positions 21 to 25 and the segments 36 to 40, 58 to 73, 87 to 96, and 113 to 114. Four residues were inserted to link the ends formed by the deletions. Half-cystine residues that had not been part of the deletions were replaced by alanine or leucine residues. The synthetic polypeptide was separated by gel filtration into a dimer and a monomer. Both fractions were purified further by ion exchange chromatography. The dimeric 70-residue S-protein analog had a specific activity of approximately 4% using RNA as substrate. It also cleaved other substrates of RNase A such as 5'-(3'-cytidylyl)-guanosine, 5'-(3'-uridylyl)-guanosine, and polycytidylic acid. The monomer of the 70-residue analog was less active but showed the same substrate specificity as the dimer. It was found that both fractions of the synthetic S-protein analog catalyzed only the transphosphorylation step of the RNase A mechanism and had very little if any activity in the hydrolysis step. Addition of natural S-peptide or S-protein did not increase the activity in the transphosphorylation reaction but greatly enhanced the reaction rate of the hydrolysis step. IN THE PRESENCE OF S-peptide, both monomeric and dimeric 70-residue S-protein, both monomeric and dimeric 70- residue S-protein analog had approximately 8% activity using cyclic cytidine 2':3'-monophosphate as substrate. The mixtures of monomer and dimer of the synthetic S-protein analog with natural S-protein generated even higher activities (151 and 74%, respectively) against this substrate despite the fact that the NH2-terminal portion of the natural enzyme (including His 12) was missing in both components of the two complexes. The 70-residue S-protein analog was completely inactive against DNA and (with one exception) against substrates for RNase T1. The close agreement of the substrate specificity of the synthetic analog with that of native RNase A in the transphosphorylation step suggested a remarkable conservation of the configuration of the active site despite drastic changes of the primary structure of the parent molecule. Possible implications of these results for the mechanism of action of RNase A are discussed.
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PMID:A synthetic 70-amino acid residue analog of ribonuclease S-protein with enzymic activity. 111 95

Histidine-40 is known to participate in phosphodiester transesterification catalyzed by the enzyme ribonuclease T1. A mutant enzyme with a lysine replacing the histidine-40 (His40Lys RNase T1) retains considerable catalytic activity [Steyaert, J., Hallenga, K., Wyns, L., & Stanssens, P. (1990) Biochemistry 29, 9064-9072]. We report on the crystal structures of His40Lys RNase T1 containing a phosphate anion and a guanosine 2'-phosphate inhibitor in the active site, respectively. Similar to previously described structures, the phosphate-containing crystals are of space group P2(1)2(1)2(1), with one molecule per asymmetric unit (a = 48.27 A, b = 46.50 A, c = 41.14 A). The complex with 2'-GMP crystallized in the lower symmetry space group P2(1), with two molecules per asymmetric unit (a = 49.20 A, b = 48.19 A, c = 40.16 A, beta = 90.26). The crystal structures have been solved at 1.8- and 2.0-A resolution yielding R values of 14.5% and 16.0%, respectively. Comparison of these His40Lys structures with the corresponding wild-type structures, containing 2'-GMP [Arni, R., Heinemann, U., Tokuoka, R., & Saenger, W. (1988) J. Biol. Chem. 263, 15358-15368] and vanadate [Kostrewa, D., Hui-Woog Choe, Heinemann, U., & Saenger, W. (1989) Biochemistry 28, 7692-7600] in the active site, respectively, leads to the following conclusions. First, the His40Lys mutation causes no significant changes in the overall structure of RNase T1; second, the Lys40 side chains in the mutant structures occupy roughly the same space as His40 in the corresponding wild-type RNase T1 structures.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Role of histidine-40 in ribonuclease T1 catalysis: three-dimensionalstructures of the partially active His40Lys mutant. 144 70

The crystal structure of RNase Rh, a new class of microbial ribonuclease from Rhizopus niveus, has been determined at 2.5 A resolution by the multiple isomorphous replacement method. The crystal structure was refined by simulated annealing with molecular dynamics. The current crystallographic R-factor is 0.200 in the 10-2.5 A resolution range. The molecular structure which is completely different from the known structures of RNase A and RNase T1 consists of six alpha-helices and seven beta-strands, belonging to the alpha+beta type structure. Two histidine and one glutamic acid residues which were predicted as the most probably functional residues by chemical modification studies are found to be clustered. The steric nature of the active site taken together with the relevant site-directed mutagenesis experiments (Irie et al.) indicates that: (i) the two histidine residues are the general acid and base; and (ii) an aspartic acid residue plays a role of recognizing adenine moiety of the substrate.
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PMID:Crystal and molecular structure of RNase Rh, a new class of microbial ribonuclease from Rhizopus niveus. 163 75

The structure of RNase F1 in aqueous solution has been studied by Raman spectroscopy and compared with that of a homologous enzyme, RNase T1. RNase F1 contains less beta-sheet and alpha-helical structure and more irregular structure than RNase T1. The strength of hydrogen bonding is weak in the beta-sheet and strong in the alpha-helix compared to that of RNase T1. Two disulfide bridges take the gauche-gauche and gauche-trans conformations, respectively. The overall hydrogen bonding of nine Tyr side chains in RNase F1 is very similar to that in RNase T1. Both of two His residues have pKa values around 8.2, which are close to those of the His residues in the active site of RNase T1. Upon binding of 2'-GMP, the hydrogen bonding of some Tyr side chains changes to a more proton-donating state. 2'-GMP is strongly hydrogen bonded with the enzyme at N7 of the guanine ring and takes the C3' endo-syn conformation. The binding mode of the inhibitor is identical to that found for RNase T1. In spite of significant differences in secondary structure, the molecular architecture of the active site seems to be highly conserved.
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PMID:Raman spectroscopic study on the structure of ribonuclease F1 and the binding mode of inhibitor. 165 Feb 48

The pK values of the histidine residues in ribonuclease T1 (RNase T1) are unusually high: 7.8 (His-92), 7.9 (His-40), and 7.3 (His-27) [Inagaki et al. (1981) J. Biochem. 89, 1185-1195]. In the RNase T1 mutant Glu-58----Ala, the first two pK values are reduced to 7.4 (His-92) and 7.1 (His-40). These lower pKs were expected since His-92 (5.5 A) and His-40 (3.7 A) are in close proximity to Glu-58 at the active site. The conformational stability of RNase T1 increases by over 4 kcal/mol between pH 9 and 5, and this can be entirely accounted for by the greater affinity for protons by the His residues in the folded protein (average pK = 7.6) than in the unfolded protein (pk approximately 6.6). Thus, almost half of the net conformational stability of RNase T1 results from a difference between the pK values of the histidine residues in the folded and unfolded conformations. In the Glu-58----Ala mutant, the increase in stability between pH 9 and 5 is halved (approximately 2 kcal/mol), as expected on the basis of the lower pK values for the His residues in the folded protein (average pK = 7.1). As a consequence, RNase T1 is more stable than the mutant below pH 7.5, and less stable above pH 7.5. These results emphasize the importance of measuring the conformational stability as a function of pH when comparing proteins differing in structure.
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PMID:Contribution of histidine residues to the conformational stability of ribonuclease T1 and mutant Glu-58----Ala. 198 Feb 7

Ribonuclease T1 and the mutant enzymes were cocrystallized with several ribonucleotides, including non-hydrolyzable substrate analogs of di- and triribonucleotides, which have a novel guanylate in which the 2'-hydroxyl group of the ribose is replaced by a fluorine atom. One of the mutant enzymes has a tryptophan residue, instead of Tyr45 of the wild-type enzyme, to enhance the binding of ribonucleotides to the enzyme and the other mutant enzyme has histidine and aspartate residues, instead of Asn43 and Asn44, respectively, to reproduce the natural substitutions found in ribonuclease Ms. Polymorphism of the crystals was observed for wild-type and mutant enzymes. However, orthorhombic crystals, which are virtually all isomorphous to each other, were successfully obtained from wild-type and mutant (Y45W) enzymes by the macroscopic seeding technique using mother crystals of the wild-type ribonuclease T1 complexed with 2'GMP or 3'GMP. The diffraction patterns of these crystals extend beyond 2.5 A resolution and the diffraction data were collected from some of the crystals on a diffractometer up to a range of 2.5 to 1.8 A resolution.
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PMID:Crystallographic characterization of wild-type and mutant ribonuclease T1 complexes with several ribonucleotides. 208 29

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