EC:3.1.27.5 - FACTA Search

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Query: EC:3.1.27.5 (RNase)
17,967 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Bovine seminal RNase (BS-RNase) is a homodimeric enzyme with a cytotoxic activity selective for tumor cells. In this study, the relationships of its cytotoxic activity to its dimeric structure and its resistance to the cytosolic RNase inhibitor (cRI) are investigated systematically by site-directed mutagenesis. The results show that (1) the dimericity of BS-RNase is essential for its full cytotoxic action; (2) the role of the dimeric structure in the antitumor activity is that of making the enzyme insensitive to the cytosolic RNase inhibitor; (3) a RNase may not be completely insensitive to cRI to exploit a full cytotoxic potential.
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PMID:Antitumor action of seminal ribonuclease, its dimeric structure, and its resistance to the cytosolic ribonuclease inhibitor. 1129 15

Carboxyl groups of bovine RNase A were amidated with ethylenediamine (to convert negative charges of carboxylate anions to positive ones), 2-aminoethanol (to eliminate negative charges), and taurine (to keep negative charges), respectively, by a carbodiimide reaction. Human RNase 1 was also modified with ethylenediamine. Surprisingly, the modified RNases were all cytotoxic toward 3T3-SV-40 cells despite their decreased ribonucleolytic activity. However, their enzymatic activity was not completely eliminated by the presence of excess cytosolic RNase inhibitor (RI). As for native RNase A and RNase 1 which were not cytotoxic, they were completely inactivated by RI. More interestingly, within the cytotoxic RNase derivatives, cytotoxicity correlated well with the net positive charge. RNase 1 and RNase A modified with ethylenediamine were more cytotoxic than naturally occurring cytotoxic bovine seminal RNase. An experiment using the fluorescence-labeled RNase derivatives indicated that the more cationic RNases were more efficiently adsorbed to the cells. Thus, it is suggested that the modification of carboxyl groups could change complementarity of RNase to RI and as a result endow RNase cytotoxicity and that cationization enhances the efficiency of cellular uptake of RNase so as to strengthen its cytotoxicity. The finding that an extracellular human enzyme such as RNase 1 could be effectively internalized into the cell by cationization suggests that cationization is a simple strategy for efficient delivery of a protein into cells and may open the way of the development of new therapeutics.
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PMID:Preparation of potent cytotoxic ribonucleases by cationization: enhanced cellular uptake and decreased interaction with ribonuclease inhibitor by chemical modification of carboxyl groups. 1141 5

A second generation mutant of dimeric human pancreas RNase (HHP2-RNase), was obtained by a single residue mutation (Glu(111)-->Gly) of the previously described dimeric human pancreas RNase variant (HHP-RNase). HHP2-RNase was found to be a highly specific antitumour agent, with an enhanced cytotoxic activity compared with HHP-RNase. The structural and functional requisites of the antitumour action of HHP2-RNase were investigated and compared with those of other dimeric antitumour RNases. The stability of the dimeric structure, i.e. the resistance of human dimeric RNase variants to reductive cleavage of the two intersubunit disulphide bonds that bridge the subunits, was determined to be an essential feature of antitumour dimeric RNases. The stability of the dimeric structure is in turn responsible for the resistance to inhibition by the cytosolic RNase inhibitor (cRI). Both the stability of the dimeric structure and the resistance to cRI inhibition appeared to be highly enhanced by an RNase substrate. This suggests a possible role for RNA in the amplification of the antitumour potential of dimeric RNases.
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PMID:Second generation antitumour human RNase: significance of its structural and functional features for the mechanism of antitumour action. 1148 73

Self-incompatibility (SI) is a genetic mechanism that restricts inbreeding in flowering plants. In the nightshade family (Solanaceae) SI is controlled by a single multiallelic S locus. Pollen rejection in this system requires the interaction of two S locus products: a stylar (S)-RNase and its pollen counterpart (pollen S). pollen S has not yet been cloned. Our understanding of how this gene functions comes from studies of plants with mutations that affect the pollen but not the stylar SI response (pollen-part mutations). These mutations are frequently associated with duplicated S alleles, but the absence of an obvious additional allele in some plants suggests pollen S can also be deleted. We studied Nicotiana alata plants with an additional S allele and show that duplication causes a pollen-part mutation in several different genetic backgrounds. Inheritance of the duplication was consistent with a competitive interaction model in which any two nonmatching S alleles cause a breakdown of SI when present in the same pollen grain. We also examined plants with presumed deletions of pollen S and found that they instead have duplications that included pollen S but not the S-RNase gene. This finding is consistent with a bipartite structure for the S locus. The absence of pollen S deletions in this study and perhaps other studies suggests that pollen S might be required for pollen viability, possibly because its product acts as an S-RNase inhibitor.
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PMID:Genetic analysis of Nicotiana pollen-part mutants is consistent with the presence of an S-ribonuclease inhibitor at the S locus. 1175 74

Cationization of a protein is considered to be a powerful strategy for internalizing a functional protein into cells. Cationized proteins appear to adsorb to the cell surface by electrostatic interactions, then enter the cell in a receptor- and transporter-independent fashion. Thus, in principle, all cell types appear to take up cationized proteins. Since ribonucleases (RNases) have a latent cytotoxic potential, cationized RNases could be useful cancer chemotherapeutics. In this study, we investigated the effect of the degree of cationization on the cytotoxicity of RNase A by modifying carboxyl groups with ethylenediamine. We found that there is an optimum degree of modification for cytotoxicity, in which 5 to 7 out of 11 carboxyl groups in RNase A are modified, toward MCF-7 and 3T3-SV-40 cells. More interestingly, the cytotoxicity of cationized RNase As correlates well with the value of [RNase activity] x [estimated concentration of RNase free from RNase inhibitor], mimicking the practical enzymatic activity of cationized RNase As in cytosol. The results indicate that cationization of a protein to an optimum level is important for maintaining protein function in the cytosol. Sophisticated protein cationization techniques will help to advance protein transduction technology.
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PMID:Optimum modification for the highest cytotoxicity of cationized ribonuclease. 1215 19

Pyrimidine-specific ribonucleases are a superfamily of structurally related enzymes with distinct catalytic and biological properties. We used a combination of enzymatic and non-enzymatic assays to investigate the release of such enzymes by isolated cells in serum-free and serum-containing media. We found that human endothelial cells typically expressed large amounts of a pancreatic-type RNase that is related to, if not identical to, human pancreatic RNase. This enzyme exhibits pyrimidine-specific catalytic activity, with a marked preference for poly(C) substrate over poly(U) substrate. It was potently inhibited by placental RNase inhibitor, the selective pancreatic-type RNase inhibitor Inhibit-Ace, and a polyclonal antibody against human pancreatic RNase. The enzyme isolated from medium conditioned by immortalized umbilical vein endothelial cells (EA.hy926) possesses an amino-terminal sequence identical to that of pancreatic RNase, and shows molecular heterogeneity (molecular weights 18,000-26,000) due to different degrees of N-glycosylation. Endothelial cells from arteries, veins, and capillaries secreted up to 100 ng of this RNase daily per million cells, whereas levels were low or undetectable in media conditioned by other cell types examined. The corresponding messenger RNA was detected by RT-PCR in most cell types tested so far, and level of its expression was in keeping with the amounts of protein. The selective strong release of pancreatic-type RNase by endothelial cells suggests that it is endowed with non-digestive functions and involved in vascular homeostasis.
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PMID:Human endothelial cells selectively express large amounts of pancreatic-type ribonuclease (RNase 1). 1221 Jul 60

There have been some attempts to develop immunotoxins utilizing human RNase as a cytotoxic domain of antitumor agents. We have recently shown that only human RNase 3 (eosinophil cationic protein, ECP) among five human pancreatic-type RNases excels in binding to the cell surface and has a growth inhibition effect on several cancer cell lines, even though the RNase activity of RNase 3 is completely inhibited by the ubiquitously expressed cytosolic RNase inhibitor. This phenomenon may be explained by that RNase 3 is very stable against proteolytic degradation because RNase 3 internalized through endocytosis could have a longer life time in the cytosol, resulting in the accumulation of enough of it to exceed the concentration of RNase inhibitor, which allows the degradation of cytosolic RNA molecules. Thus, we compared the stabilities of human pancreatic-type RNases (RNases 1-5) and bovine RNase A by means of guanidium chloride-induced denaturation experiments based on the assumption of a two-state transition for unfolding. It was demonstrated that RNase 3 is extraordinarily stabler than either RNase A or the other human RNases (by more than 25 kJ/mol). Thus, our data suggest that in addition to its specific affinity for certain cancer cell lines, the stability of RNase 3 contributes to its unique cytotoxic effect and that it is important to stabilize a human RNase moiety through protein engineering for the design of human RNase-based immunotoxins.
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PMID:RNase 3 (ECP) is an extraordinarily stable protein among human pancreatic-type RNases. 1241 23

RNase inhibitor (RI) binds diverse proteins in the pancreatic RNase superfamily with extremely high avidity. Previous studies showed that tight binding of RNase A and angiogenin (Ang) is achieved primarily through interactions of hot spot residues in the 434-460 C-terminal segment of RI with the enzymatic active site; Asp435 of RI forms key hydrogen bonds with the catalytic lysine in both complexes, whereas the other contacts are largely distinctive. Here we have investigated the structural basis for recognition of a third ligand, eosinophil-derived neurotoxin (EDN), by single-site and multisite mutagenesis. Surprisingly, Ala replacement of Asp435 decreases affinity for EDN only by 14-fold, as compared to the several hundred-fold decreases with RNase A and Ang, and individual mutations of three other hot spot residues-Tyr434, Tyr437, and Ser460-have essentially no effect. Ala substitutions of nine additional residues, selected by examining a computational model of the RI.EDN complex, also have no marked impact. Overall, the losses in affinity for the single-residue variants examined account for only approximately 25% of the free energy of binding for the complex. However, multisite mutagenesis of RI reveals strong superadditivity of mutational effects, indicating that part of this shortfall reflects negative cooperativity. Replacement of Tyr434 together with Asp435 or Tyr437 increases K(i) by 540- and 290-fold, respectively. Thus, the C-terminal region of RI again plays an important role in ligand recognition, although probably smaller than for binding RNase A and Ang. Simultaneous substitutions of three neighboring tryptophans (261, 263, and 318) on RI attenuate affinity even more dramatically (by 4900-fold), indicating that the interactions of this RI region also contribute a considerable amount of the binding energy for the EDN complex. These findings highlight the potential importance of cooperativity in protein-protein interactions and the consequent limitations of single-site mutagenesis for assessing interface energetics.
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PMID:Mutational analysis of the complex of human RNase inhibitor and human eosinophil-derived neurotoxin (RNase 2). 1257 57

The dimeric structure of seminal ribonuclease (BS-RNase) is maintained by noncovalent interactions and by two intersubunit disulfide bridges. Another unusual feature of this enzyme is its antitumour action, consisting in a cytotoxic activity selective for malignant cells. This cytotoxic action is exerted when the protein reaches the cytosol of the affected cells, where it degrades ribosomal RNA, thus blocking protein synthesis and leading cells to death. The current model proposed for the mechanism of antitumour action of BS-RNase is based on the ability of the protein to resist the neutralizing action of the cytosolic RNase inhibitor, a resistance due to the dimeric structure of the enzyme. Monomeric RNases, and monomeric derivatives of BS-RNase, are strongly bound by the inhibitor and inactive as antitumor agents. Here we report on monomeric derivatives of BS-RNase that, although strongly inhibited by the cytosolic RNase inhibitor, are cytotoxic towards malignant cells. These monomers are produced by reductive cleavage of the intersubunit disulfides of the native, dimeric protein followed by linking the exposed sulfhydryls to small thiols through formation of mixed disulfides. We found that sulfhydryls from cell monolayers and cell membranes can attack these mixed disulfides in the monomeric derivatives, and reconstitute, through sulfhydryl-disulfide interchange reactions, the native dimeric protein, which is internalized as such, and displays its antitumour action.
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PMID:A role for the intersubunit disulfides of seminal RNase in the mechanism of its antitumor action. 1270 57

Rat eosinophils contain eosinophil-associated ribonucleases (Ears) in their granules. Ears are thought to be synthesized as pre-forms and stored in the granules as mature forms. However, the N-terminal amino acid of mature Ear-1 and Ear-2 is still controversial. Therefore, we prepared two recombinant mature forms of Ear-1 and Ear-2 in which the N-terminal amino acids are Ser24 (S) [Ear-1 (S) and Ear-2 (S)] and Gln26 (Q) [Ear-1 (Q) and Ear-2 (Q)], and analyzed their biological activities by comparing them with those of pre-form Ear-1 and pre-form Ear-2. The four mature Ears showed RNase A activity as well as bovine pancreatic RNase A activity, but pre-Ear-1 and pre-Ear-2 showed no RNase A activity. Mature Ear-1 (Q) and mature Ear-2 (Q) showed more potent RNase A activity than mature Ear-1 (S) and mature Ear-2 (S), respectively. The RNase A activities of mature Ear-1 (Q) and mature Ear-2 (Q) were reduced by treatment at 96 degrees C for 20 min or with RNase inhibitor. The growth of Escherichia coli was inhibited by both pre-Ears and mature Ears in a concentration-dependent manner, and was almost completely suppressed at 1.0 microM. The bactericidal activities of mature Ear-1 (Q) and mature Ear-2 (Q) were not inhibited by RNase inhibitor, but was increased by treatment at 96 degrees C for 20 min.
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PMID:Preparation of recombinant rat eosinophil-associated ribonuclease-1 and -2 and analysis of their biological activities. 1285 22

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