EC:3.1.26.9 - FACTA Search

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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)

Suspensions of rat pancreatic microsomal fraction release alpha-amylase and ribonuclease on incubation at 37 degrees C, but not at 2 degrees C. The release is abolished by proteolytic enzymes. Ribonuclease associated with the microsomal fraction is protected from subtilisin BPN' attack, but is sensitive after release.
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PMID:Proteinase-sensitive release of enzymes from pancreatic microsomal fraction. 31 Nov 98

Trypsin, pepsin and subtilisin have been used as conformational probes for the structure of bovine seminal ribonuclease BS-1 by studying, under definite conditions, their effects on the seminal enzyme, a dimeric protein made up to two identical subunits; on bovine pancreatic monomeric ribonuclease A (EC 3.1.4.22) with a polypeptide chain homologous to that of the seminal ribonuclease subunit chain; and on a monomeric, active and stable derivative of seminal ribonuclease. The results show: (1) that the C-terminal regions of the pancreatic and the seminal proteins are very similar as they appear to fit in an identical way to the active site of pepsin; (2) that the resistance of the N-terminal region of ribonuclease BS-1 to subtilisin is not due to the dimeric structure of the protein, but to the conformation of this region, where an essential feature is the presence of a proline residue at position 19; (3) that the monomer of ribonuclease BS-1 is resistant to tryptic action only when bound to the partner monomer in the quaternary structure of the protein. This indicates that dissociation of the seminal ribonuclease makes some potentially susceptible susceptible bond or bonds available to trypsin either through a conformational change of the protein subunit, or by simply exposing the protein area hidden at the intersubunit interfaces.
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PMID:Proteolytic enzymes as structural probes for ribonuclease BS-1. 78 46

Limited proteolysis of RNAase-Aa(1) (monodeamidated ribonuclease-A) by subtilisin results in the formation of an active RNAase-S type of derivative, namely RNAase-Aa(1)S. RNAase-Aa(1)S was chromatographically distinct from RNAase-S, but exhibited very nearly the same enzymic activity, antigenic conformation and susceptibility to trypsin as did RNAase-S. Fractionation of RNAase-Aa(1)S by trichloroacetic acid yielded RNAase-Aa(1)S-protein and RNAase-Aa(1)S-peptide, both of which are inactive by themselves, but regenerate active RNAase-Aa(1)S' when mixed together. RNAase-Aa(1)S-peptide was identical with RNAase-S-peptide, whereas the protein part was distinct from that of RNAase-S-protein. Titration of RNAase-Aa(1)S-protein with S-peptide exhibited slight but noticeably weaker binding of the peptide to the deamidated S-protein as compared with that of native protein. Unlike the subtilisin digestion of RNAase-A, which gives nearly 100% conversion into RNAase-S, the digestion of RNAase-Aa(1) gives only a 50% conversion. The resistance of RNAase-Aa(1) to further subtilisin modification after 50% conversion is apparently due to the interaction of RNAase-Aa(1) with its subtilisin-modified product. RNAase-S was also found to undergo activity and structural changes in acidic solutions, similar to those of RNAase-A. The initial reaction product (RNAase-Sa(1)) isolated by chromatography was not homogeneous. Unlike the acid treatment of RNAase-A, which affected only the S-protein part, the acid treatment of RNAase-S affected both the S-protein and the S-peptide region of the molecule.
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PMID:Subtilisin modification of monodeamidated ribonuclease-A. 92 53

Bison pancreatic ribonuclease was isolated by affinity chromatography. Thermolysin and tryptic digestion of denaturated protein, and subtilisin digestion of native protein yielded peptides, which were purified and submitted to amino acid analysis. These peptides, together with partial sequence data obtained by Stewart & Stevenson (16) overlap the entire amino acid sequence of bison ribonuclease. No differences with bovine ribonuclease were found, although there may be differences in state of amidation of some residues.
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PMID:Studies on the primary structure of bison pancreatic ribonuclease. 95 81

A homology has been found between an octapeptide involved in attachment of the human immunodeficiency virus to helper/inducer T cells and an octapeptide segment of bovine pancreatic ribonuclease A. This segment (residues 19-26) contains the sites for subtilisin cleavage of this enzyme into the S-peptide and S-protein. From the X-ray crystal structure of ribonuclease, this sequence is known to be exposed to solvent and interacts little with the rest of the protein. A structure for the human immunodeficiency virus attachment peptide can be deduced from this homology, as a well-defined structure has been determined for this sequence in ribonuclease. This can be readily accomplished using previously developed computer methods based upon conformational energy calculations. The calculated structure for human immunodeficiency virus peptide is identical to the ribonuclease segment (19-26) in backbone conformation. It is stabilized by internal interactions of nonpolar residues, and by exposure of polar hydroxyl groups. The results suggest that the T-cell human immunodeficiency virus receptor may be hydrophilic in nature and that conservation of the sequence in two presumably functionally unrelated proteins is related to the need for conservation of exposed structure.
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PMID:A strong homology exists between the active T-cell binding gp120 octapeptide of human immunodeficiency virus and the subtilisin cleavage peptide of bovine ribonuclease A. 303 Mar 17

The primary structure of angiogenin is 33% identical to that of bovine pancreatic ribonuclease (RNase), but the enzymatic activities of the two proteins differ markedly. Similarly, their susceptibilities to limited proteolysis differ as well. In contrast to RNase, angiogenin totally resists proteolysis by subtilisin. Indeed, among 16 proteases examined, only endoprotease Lys-C, trypsin, and pepsin are able to cleave angiogenin. Even with prolonged incubation, endoprotease Lys-C selectively cleaves the Lys-60-Asn-61 bond; the product retains full ribonucleolytic activity. Initially, trypsin also cleaves this same bond, but with time it causes extensive degradation. Pepsin, at pH 2, cleaves the Phe-9-Leu-10 bond, to give angiogenin (10-123), which displays approximately 15% of the native activity toward ribosomal RNA (rRNA). The susceptibility to proteolysis and/or the sites of cleavage of angiogenin and bovine RNase differ markedly despite their structural homology. These differences are considered in terms of the amino acid sequences of the two proteins.
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PMID:Conformational characterization of human angiogenin by limited proteolysis. 315 Dec 51

Intracellular serine protease, termed ISP-103, was isolated from Bacillus subtilis, strain 103. The substrate specificity of the enzyme was compared to that of secretory subtilisins. Similar to subtilisins, ISP-103 cleaves a single peptide bond Ala20-Ser21 within the native pancreatic ribonuclease A, which results in the accumulation of trypsin-sensitive ribonuclease S, consisting of a non-covalently bound S-peptide (20 amino acid residues) and S-protein (104 amino acid residues). The enzyme hydrolyzes a single peptide bond Leu15-Tyr16 of the B-chain of oxidized bovine insulin, in contrast to the subtilisins cleaving four additional bonds. ISP prefers Leu rather than Phe in the P1 binding site of the rho-nitroanilide peptide substrates and shows a more strict dependence of the activity on the presence of the hydrophobic residues in the P2 and P3 sites. The data obtained indicate that the substrate specificity of ISP, being within the borders of subtilisin specificity, is nevertheless much more restricted.
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PMID:[Substrate specificity of Bacillus subtilis intracellular serine protease. Hydrolysis of insulin beta-chain, native ribonuclease A and p-nitroanilide peptide substrates]. 626 Feb 44

A useful approach using an MLEV-17 pulse sequence was developed to identify histidine C epsilon 1H magnetic resonances of proteins. This technique can be readily applied to proteins dissolved directly in deuterium oxide solution and eliminates the necessity for an exhaustive exchange of NH to ND. Because of its sensitivity, this technique makes it possible to significantly extend the limitations on protein size. The utility of this spin-lock sequence is demonstrated using ribonuclease, subtilisin, and human prostatic acid phosphatase, with molecular weights ranging from 12K to 100K. With this technique, all three or four of the histidine 1H NMR signals of two human low-molecular-weight phosphotyrosyl protein phosphatases (HCPTP-A or -B, respectively) were readily detected. Histidine peak assignments were accomplished through the use of histidine to alanine mutants of HCPTP-A and -B and a homologous bovine enzyme. Analysis of the pH titration curves of these signals provided microscopic pKa's for the histidines in the human enzymes. A comparison of corresponding histidine pKa values of the two isoenzymes, together with an examination of the 1H NMR spectra of the proteins, provided evidence of significant differences in secondary structure. Titration of HCPTP-A and -B with vanadate, a strongly bound competitive inhibitor, caused the His-72 peak to appear as two signals at nearly equimolar concentrations of protein and vanadate, while the other histidine peaks were not affected. This is interpreted to mean that His-72 is at the enzyme active site.
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PMID:Identification and pKa determination of the histidine residues of human low-molecular-weight phosphotyrosyl protein phosphatases: a convenient approach using an MLEV-17 spectral editing scheme. 768 32

An engineered variant of subtilisin BPN', termed subtiligase, which efficiently ligates esterified peptides in aqueous solution, was used for the complete synthesis of ribonuclease (RNase) A that contains unnatural catalytic residues. Fully active RNase A (124 residues long) was produced in milligram quantities by stepwise ligation of six esterified peptide fragments (each 12 to 30 residues long) at yields averaging 70 percent per ligation. Variants of RNase A were produced in which the catalytic histidines at positions 12 and 119 were substituted with the unnatural amino acid 4-fluorohistidine, which has a pKa of 3.5 compared to 6.8 for histidine. Large changes in the profile of the pH as it affects rate occurred for the single and double mutants with surprisingly little change in the kcat for either the RNA cleavage or hydrolysis steps. The data indicate that these imidazoles function as general acids and bases, but that the proton transfer steps are not rate-limiting when the imidazoles are present in their correct protonation states. These studies indicate the potential of subtiligase for the blockwise synthesis of large proteins.
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PMID:A designed peptide ligase for total synthesis of ribonuclease A with unnatural catalytic residues. 793 59

Derivatives of ribonuclease A (RNase A) with modifications in positions 1 and/or 7 were prepared by subtilisin-catalyzed semisynthesis starting from synthetic RNase 1-20 peptides and S-protein (RNase 21-124). The lysyl residue at position 1 was replaced by alanine, whereas Lys-7 was replaced by cysteine that was specifically modified prior to semisynthesis. The enzymes obtained were characterized by protein chemical methods and were active toward uridylyl-3',5'-adenosine and yeast RNA. When Lys-7 was replaced by S-methyl-cysteine or S-carboxamido-contrast, the catalytic properties were only slightly altered. The dissociation constant for the RNase A-RI complex increased from 74 fM (RNase A) to 4.5 pM (Lys-1, Cys-7-methyl RNase), corresponding to a decrease in binding energy of 10 kJ mol-1. Modifications that introduced a positive charge in position 7 (S-aminoethyl- or S-ethylpyridyl-cysteine) led to much smaller losses. The replacement of Lys-1 resulted in a 4-kJ mol-1 loss in binding energy. S-protein bound to RI with Ki = 63.4 pM, 800-fold weaker than RNase A. This corresponded to a 16-kJ mol-1 difference in binding energy. The results show that the N-terminal portion of RNase A contributes significantly to binding of ribonuclease inhibitor and that ionic interactions of Lys-7 and to a smaller extent of Lys-1 provide most of the binding energy.
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PMID:Interaction of semisynthetic variants of RNase A with ribonuclease inhibitor. 800 61

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