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

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Query: EC:3.1.26.9 (ribonuclease)
6,589 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We present the spatial structure of binase, a small extracellular ribonuclease, derived from 1H-NMR* data in aqueous solution. The total of 20 structures were obtained via torsion angle dynamics using DYANA program with experimental NOE and hydrogen bond distance constraints and phi and chi1 dihedral angle constraints. The final structures were energy minimised with ECEPP/2 potential in FANTOM program. Binase consists of three alpha-helices in N-terminal part (residues 6-16, 26-32 and 41-44), five-stranded antiparallel beta-sheet in C-terminal part (residues 51-55, 70-75, 86-90, 94-99 and 104-108) and two-stranded parallel beta-sheet (residues 22-24 and 49-51). Three loops (residues 36-39, 56-67 and 76-83), which play significant role in biological functioning of binase, are flexible in solution. The differences between binase and barnase spatial structures in solution explain the differences in thermostability of binase, barnase and their hybrids.
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PMID:Three-dimensional structure of binase in solution. 970 13

Protein B23 is an abundant nucleolar protein and a putative ribosome assembly factor which possesses an intrinsic ribonuclease activity. In the current work, the effects of RNA sequence and secondary structure on the cleavage preference by protein B23 were studied. Protein B23 ribonuclease preferentially cleaved the single-stranded homopolymers poly(A), poly(U) and poly(C). However, double-stranded co-polymers and poly(G) were resistant to cleavage. No base specificity was observed with an oligoribonucleotide substrate. The action of protein B23 ribonuclease on different regions of pre-rRNA was studied using transcripts synthesized in vitro from cloned rDNA segments. Although no specific cleavages were detected in transcripts containing sequences from the 5' external transcribed spacer or the first internal transcribed spacer, the enzyme preferentially cleaved the second internal transcribed spacer (ITS2) approximately 250 nt downstream from the 3'-end of 5.8S rRNA. Preferential cleavage was retained when the transcript was extended by 100 nt at the 3'-end, but abolished in a transcript lacking this cleavage site. Furthermore, this site was not susceptible to cleavage by RNase A or RNase T1. These results, in conjunction with the sub-nucleolar localization of the protein with elements of the processing machinery, suggest that the protein B23 endoribonuclease could play a role in pre-rRNA processing in ITS2.
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PMID:Preferential cleavage in pre-ribosomal RNA byprotein B23 endoribonuclease. 974 56

We report the 1.7 A resolution structure of RNase Sa complexed with the polypeptide inhibitor barstar. The crystals are in the hexagonal space group P65 with unit-cell dimensions a = b = 56.9, c = 135.8 A and the asymmetric unit contains one molecule of the complex. RNase Sa is an extracellular microbial ribonuclease produced by Streptomyces aureofaciens. Barstar is the natural inhibitor of barnase, the ribonuclease of Bacillus amyloliquefaciens. It inhibits RNase Sa and barnase in a similar manner by steric blocking of the active site. The structure of RNase Sa is very similar to that observed in crystals of the native enzyme and its complexes with nucleotides. Barstar retains the structure found in its complex with barnase. The accessible surface area of protein buried in the complex is about 300 A2 smaller and there are fewer hydrogen bonds in the enzyme-inhibitor interface in RNase Sa-barstar than in barnase-barstar, providing an explanation of the reduced binding affinity in the former. Previous studies of barstar complexes have used mutants of the inhibitor and this is the first structure which includes wild-type barstar.
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PMID:Recognition of RNase Sa by the inhibitor barstar: structure of the complex at 1.7 A resolution. 975 10

RNase Sa, an extracellular ribonuclease produced by Streptomyces aureofaciens, is inhibited by barstar, the natural protein inhibitor of barnase, the ribonuclease of Bacillus amyloliquefaciens. The complex of RNase Sa with wild-type barstar was crystallized by hanging-drop vapour diffusion. It was shown by sodium dodecyl sulfate polyacrylamide gel electrophoresis that RNase Sa and barstar are present in equimolar proportions in the crystals. The crystals are in the hexagonal space group P65 with unit cell dimensions a = b = 56.95, c = 135.8 A. They diffract to 1.7 A resolution at the DESY synchronton source. The asymmetric unit contains one molecule of the complex.
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PMID:Crystallization and preliminary X-ray investigation of the complex of RNase Sa with wild-type barstar. 976 9

In principle, all biochemical reactions are reversible, though some are more reversible than others. The classical ribonuclease mechanism involves a reversible transphosphorylation step, followed by quasi irreversible hydrolysis of the cyclic intermediate. We performed isotope-exchange and intermediate-trapping experiments showing that the second hydrolysis step is readily reversible in the presence of RNase A or RNase T1. As a consequence, the equilibrium between a phosphodiester and a 2',3'-cyclophosphate accounts for all catalysed reactions, even if the leaving/attacking group is a water molecule. Therefore, ribonucleases are transferases rather than hydrolases. The equilibrium constant for the catalysed interconversion is close to 1 M. From this result, we estimate the effective concentration of the 2'-hydroxyl nucleophile in the cyclization step to be 10(7) M. The high effective concentration of the vicinal hydroxyl group balances the strain-associated and solvation-associated instability of the pentacyclic phosphodiester.
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PMID:Reconsidering the energetics of ribonuclease catalysed RNA hydrolysis. 979 30

The contribution of hydrogen bonding by peptide groups to the conformational stability of globular proteins was studied. One of the conserved residues in the microbial ribonuclease (RNase) family is an asparagine at position 39 in RNase Sa, 44 in RNase T1, and 58 in RNase Ba (barnase). The amide group of this asparagine is buried and forms two similar intramolecular hydrogen bonds with a neighboring peptide group to anchor a loop on the surface of all three proteins. Thus, it is a good model for the hydrogen bonding of peptide groups. When the conserved asparagine is replaced with alanine, the decrease in the stability of the mutant proteins is 2.2 (Sa), 1.8 (T1), and 2.7 (Ba) kcal/mol. When the conserved asparagine is replaced by aspartate, the stability of the mutant proteins decreases by 1.5 and 1.8 kcal/mol for RNases Sa and T1, respectively, but increases by 0.5 kcal/mol for RNase Ba. When the conserved asparagine was replaced by serine, the stability of the mutant proteins was decreased by 2.3 and 1.7 kcal/mol for RNases Sa and T1, respectively. The structure of the Asn 39 --> Ser mutant of RNase Sa was determined at 1.7 A resolution. There is a significant conformational change near the site of the mutation: (1) the side chain of Ser 39 is oriented differently than that of Asn 39 and forms hydrogen bonds with two conserved water molecules; (2) the peptide bond of Ser 42 changes conformation in the mutant so that the side chain forms three new intramolecular hydrogen bonds with the backbone to replace three hydrogen bonds to water molecules present in the wild-type structure; and (3) the loss of the anchoring hydrogen bonds makes the surface loop more flexible in the mutant than it is in wild-type RNase Sa. The results show that burial and hydrogen bonding of the conserved asparagine make a large contribution to microbial RNase stability and emphasize the importance of structural information in interpreting stability studies of mutant proteins.
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PMID:Contribution of a conserved asparagine to the conformational stability of ribonucleases Sa, Ba, and T1. 981 11

This paper describes the use of fluorescence quenching and dequenching to analyze molecular interactions of RNA in vitro and in vivo. Fluorescein-labeled ribonucleotide was incorporated into an RNA substrate by in vitro transcription. The fluorescence quantum yield of the intact RNA was reduced by intramolecular quenching. When the RNA was degraded by ribonuclease digestion, the quantum yield increased by approximately 50%, reflecting dequenching due to separation of proximate fluorophores. Dequenching was dependent on the concentration of enzyme and substrate and was inhibited by the ribonuclease inhibitor RNasin. Comparable rates of dequenching were observed with RNase A and RNase T1. Dequenching provides a sensitive, quantitative, and convenient assay for RNA degradation. When fluorescent RNA was microinjected into cells in culture the intracellular fluorescence declined gradually with time after injection reflecting "superquenching: due to intermolecular interactions between the injected RNA and intracellular components. Capped RNA exhibited greater superquenching than uncapped RNA. Superquenching provides a sensitive, quantitative, and specific assay with subcellular resolution for intermolecular interactions of RNA in vivo. When RNase was injected into the same cells, fluorescence increased by approximately 50%, indicating that fluorescence dequenching due to RNA degradation can be measured in vivo as well as in vitro.
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PMID:Fluorescence quenching and dequenching analysis of RNA interactions in vitro and in vivo. 986 74

Ternary complexes of RNA polymerase containing the DNA template and nascent RNA are the intermediates in transcript elongation in all cells. We have footprinted the RNA transcript with single-strand-specific ribonucleases in ternary complexes of Escherichia coli RNA polymerase. When complexes are treated with elevated levels of ribonucleases A and T1, the nascent transcript can be cleaved to within 3-4 nucleotides of the 3'-terminus. Ternary complexes containing ribonuclease-cleaved transcripts as short as 3 nucleotides remain stable and active, ensuring that the cleavage occurred within an active ternary complex. However, cleavage by ribonuclease I is restricted, and gives a limited digest product of about 16 nt. At lower concentrations of ribonuclease T1, two regions of partial protection are seen. The first region extends through the first 15-16 nucleotides from the 3'-OH terminus; the second region extends from position 30 out to position 45. We interpret these regions of partial protection as defining two RNA product binding sites on the RNA polymerase that bind the product to the enzyme during elongation. Our results rule out the existence of a stable RNA-DNA hybrid in these ternary complexes of greater than 3 base pairs in length.
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PMID:Structural analysis of ternary complexes of Escherichia coli RNA polymerase: ribonuclease footprinting of the nascent RNA in complexes. 989 Sep 1

Single amino acid residue substitutions rarely destroy the structural integrity of proteins. Substitution of glycine residues, however, is among the few sorts of alterations that can have such an effect. Here, we seek to understand what accounts for the extreme functional impairment of the bacterial ribonuclease barnase upon substitution of Gly52 or Gly53. We find that inactivation is caused by overall disruption of the folded state that manifests itself in three ways: (1) dramatically reduced stability (by 5.2 to 8.4 kcal mol-1 for mutants showing inactivation in vivo); (2) progressive loss of folded-state activity with increasing temperature, indicating a less well formed fold; and (3) substantial proteolytic degradation of mutant enzymes in vivo. Examination of two deletion mutants, missing either Gly53 or Asp54, shows that the irregular beta-bulge formed by these two residues is of vital importance to the structural integrity of barnase. The parallel behaviour of mutants carrying replacements of either of the two glycine residues therefore appears to arise from a common mechanism: disruption of local structure at the beta-bulge. The importance of this structural element to the function of barnase raises the question of whether it may be present in other RNases. The Streptomyces enzymes RNase Sa and RNase St differ considerably from barnase in both sequence and structure, yet both show significant sequence similarity to barnase over a region beginning at Gly53. Structural comparison indicates that the Streptomyces enzymes do have the barnase-like irregular beta-bulge, making this an important characteristic feature of a group of bacterial ribonucleases. The sensitivity of this feature demonstrates that detailed aspects of local structure may have a major role in determining the overall structural and functional properties of an enzyme, even where no explanation for this role is readily apparent. If this is a general characteristic of the structure-function relationship, it may pose a formidable obstacle to the de novo design of new enzymes.
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PMID:An irregular beta-bulge common to a group of bacterial RNases is an important determinant of stability and function in barnase. 1006 10

The mechanism by which barnase and binase are stabilized in their complexes with barstar and the role of the Cys-40 residue of barstar in that stabilization have been investigated by scanning microcalorimetry. Melting of ribonuclease complexes with barstar and its Cys-82-Ala mutant is described by two 2-state transitions. The lower-temperature one corresponds to barstar denaturation and the higher-temperature transition to ribonuclease melting. The barstar mutation Cys-40-Ala, which is within the principal barnase-binding region of barstar, simplifies the melting to a single 2-state transition. The presence of residue Cys-40 in barstar results in additional stabilization of ribonuclease in the complex.
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PMID:Key role of barstar Cys-40 residue in the mechanism of heat denaturation of bacterial ribonuclease complexes with barstar. 1009 94


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