EC:3.1.27.1 - FACTA Search

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Query: EC:3.1.27.1 (RNase)
16,360 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The rpsO mRNA, encoding ribosomal protein S15, is only partly stabilized when the three ribonucleases implicated in its degradation--RNase E, polynucleotide phosphorylase, and RNase II--are inactivated. In the strain deficient for RNase E and 3'-to-5' exoribonucleases, degradation of this mRNA is correlated with the appearance of posttranscriptionally elongated molecules. We report that these elongated mRNAs harbor poly(A) tails, most of which are fused downstream of the 3'-terminal hairpin at the site where transcription terminates. Poly(A) tails are shorter in strains containing 3'-to-5' exoribonucleases. Inactivation of poly(A) polymerase I (pcnB) prevents polyadenylylation and stabilizes the rpsO mRNA if RNase E is inactive. In contrast polyadenylylation does not significantly modify the stability of rpsO mRNA undergoing RNase E-mediated degradation.
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PMID:Polyadenylylation destabilizes the rpsO mRNA of Escherichia coli. 773 15

Ribonuclease II is a processive 3' exoribonuclease in Escherichia coli. It degraded substrates with 3'-OH or 2',3'-cyclicP ends slightly faster than those with 3'-P or 2'-P groups with a turnover number of approximately 70 nt/s at 37 degrees C. RNase II does not degrade DNA but the specificity for ribose was not for the cleavage bond but rather for ribo-bonds three to four nucleotides (nt) upstream, which could explain why the limit digest is a dimer. Oligonucleotides (oligos) of deoxy(C) were reversible competitive inhibitors of the enzyme and indicated a strong upstream binding site (approximately 15 to 27 nt from the 3' end). These oligos could protect RNase II from inactivation by heat or from diethylpyrocarbonate, an agent that preferentially reacts with His residues. Compared to oligo(dC), oligos of (dA) were at least 500 times less effective inhibitors of RNase II. Using mixed oligo(dAdC) inhibitors, an obligatory 3' to 5' direction of binding into the catalytic site was shown. From the reaction kinetics of RNase II under different conditions it was concluded that the enzyme recognition differs for poly(A), poly(C) and poly(U). Poly(C) was degraded more slowly than poly(A) or poly(U) with a 3.5 times slower Vmax, while rate differences between small oligos were extreme; oligo(A)7 was degraded > 100 times faster than oligo(C)7. Ethanol, which weakens hydrophobic interactions, increased the reaction velocity of poly(C) to that of poly(A) and poly(U). It had no effect on the reaction velocities of poly(A) or poly(U), but decreased the binding of poly(A) markedly. Oligo(A) was bound more strongly to a hydrophobic column than was oligo(C). Salt, which affects charge interactions, decreased the binding affinity and/or association rate of poly(C) to RNase II, had a lesser effect on poly(U), but the reactions of poly(A) were unaffected even in much higher concentrations of salt. A clue to the slower reaction velocity of poly(C) was shown when the reaction intermediates were viewed by PAGE. At lower temperatures of reaction (< 25 degrees C), there were more intense bands separated by discrete distances of approximately 12 nt during the degradation of poly(C) by RNase II. Chase experiments showed that these stops were accounted for by dissociation of poly(C) from the enzyme. They were not seen when poly(C) was degraded at 37 degrees C or degraded in the presence of 20% ethanol at any temperatures, nor were they seen when poly(A) or poly(U) was degraded even at low temperatures.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The processive reaction mechanism of ribonuclease II. 796 9

Poly[2'-O-(2,4-dinitrophenyl)]poly(A)[DNP-poly(A)] has been found to be a potent inhibitor in solution for RNases A, B, S, T1, T2 and H as well as phosphodiesterases I and II. Kinetic measurements with RNase B and RNase T1 showed DNP-poly(A) to be a reversible competitive inhibitor with K1 equal to 1.03 and 1.05 microM, respectively. Data on the quenching of fluorescence of RNase T1 by DNP-poly(A) indicate the existence of more than one RNase-binding site in each DNP-poly(A) molecule. By attaching each DNP-poly(A) molecule at one end covalently to oxirane acrylic beads, an affinity column was prepared for selective removal of RNases from aqueous solutions by simple filtration. It was found that a 1000-fold reduction in RNase concentration can be obtained by passing either 7.0 microM or 7.0 nM RNase A solution through a 5-cm-long column. The column can be saturated by passing through a concentrated RNase solution and subsequently regenerated by washing with salt solution. The regenerated column can be used repeatedly with no significant decrease in RNase-binding affinity and capacity. By titration of the derivatized beads with RNase, the first dissociation constant (Kd) and binding capacity for the bound enzyme can be determined. The (Kd) was found to be 0.66 microM for RNase B and 0.48 microM for RNase T1; the corresponding binding capacities were found to be 21.0 x (10)-8 and 9.6 x (10)-8 mol/g, respectively.
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PMID:Selective removal of ribonucleases from solution with covalently anchored macromolecular inhibitor. 877 29

The degradation process of the rpsO mRNA is one of the best characterised in E coli. Two independent degradation pathways have been identified. The first one is initiated by an RNase E endonucleolytic cleavage which allows access to the transcript by polynucleotide phosphorylase and RNase II. Cleavage by RNase E gives rise to an rpsO message lacking the stabilising hairpin of the primary transcript; this truncated mRNA is then degraded exonucleolytically from its 3' terminus. This pathway might be coupled to the translation of the message. The second pathway allows degradation of polyadenylated rpsO mRNA independently of RNase II, PNPase and RNase E. The ribonucleases responsible for degradation of poly(A) mRNAs under these conditions are not known. Poly(A) tails have been proposed to facilitate the degradation of structured RNA by polynucleotide phosphorylase. In contrast, we believe that removal of poly(A) by RNase II stabilises the rpsO mRNA harbouring a 3' hairpin. In addition to these two pathways, we have identified endonucleolytic cleavages which occur only in strains deficient for both RNase E and RNase III suggesting that these two endonucleases protect the 5' leader of the mRNA from the attack of unidentified ribonuclease(s). Looping of the rpsO mRNA might explain how RNase E bound at the 5' end can cleave at a site located just upstream the hairpin of the transcription terminator.
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PMID:Multiple degradation pathways of the rpsO mRNA of Escherichia coli. RNase E interacts with the 5' and 3' extremities of the primary transcript. 891 31

Inhibition and substrate competition kinetics demonstrated that tRNA is a highly preferred substrate of thyroid alkaline RNase. The pyrimidine-specific RNase cleaved poly(C) 2.8 x 10(5) faster than poly(U). kcat:K(M) ratios for tRNA and poly(C) based on molecular weights failed to predict preference when both were present. Competition experiments between poly(C) and tRNA revealed tRNA was a tight-binding competing substrate and the cytidylate residues in the 3'-CCA terminus to tRNA were preferred about 280:1 over those in poly(C). Poly(U) was competitive with tRNA. When poly(C) was the substrate, inhibition type by poly(G) depended on poly(G) concentration. Neither tRNA lacking its 3' terminal cytidylyl(3'-5')adenosine and terminating in a 2':3' cCMP residue, tRNA lacking its 3' terminal 5'AMP residue, guanosine, nor guanylyl(3'-5')guanylyl(3'-5')guanosine were inhibitors. Product inhibition by adenosine and 2':3' cCMP showed the kinetic mechanism for cleavage of tRNA was ordered uni bi.
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PMID:Inhibition and substrate competition kinetics in analysis of porcine thyroid alkaline ribonuclease's specificity toward synthetic RNA's and tRNA. 931 16

A ribonuclease with a molecular weight of 29 kDa as determined by FPLC-gel filtration on Superose 12 was isolated from the sclerotia of the mushroom Pleurotus tuber-regium using a procedure involving extraction with aqueous buffer, ion exchange chromatography on DEAE-cellulose, affinity chromatography on Affi-gel blue gel, ion exchange chromatography on CM-cellulose, and FPLC on Mono S. The protein was unadsorbed on DEAE-cellulose but adsorbed on Affi-gel blue gel and CM-cellulose. It was homodimeric, made up of two identical subunits, each with a molecular weight of 14.5 kDa as witnessed in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It exhibited potent ribonucleolytic activity toward Poly G. Its ribonucleolytic activity was resistant to heating at 100 degreesC for 30 min, but was inhibited by HgCl2, ZnSO4, NiSO4, CaCl2, and Pb(NO3)2.
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PMID:A ribonuclease from sclerotia of the edible mushroom Pleurotus tuber-regium. 978 79

The rpsO mRNA of E. coli encoding ribosomal protein S15 is destabilized by poly(A) tails posttranscriptionally added by poly(A)polymerase I. We demonstrate here that polyadenylation also contributes to the rapid degradation of mRNA fragments generated by RNase E. It was already known that an RNase E cleavage occurring at the M2 site, ten nucleotides downstream of the coding sequence of rpsO, removes the 3' hairpin which protects the primary transcript from the attack of polynucleotide phosphorylase and RNase II. A second RNase E processing site, referred to as M3, is now identified at the beginning of the coding sequence of rpsO which contributes together with exonucleases to the degradation of messengers processed at M2. Cleavages at M2 and M3 give rise to mRNA fragments which are very rapidly degraded in wild-type cells. Poly(A)polymerase I contributes differently to the instability of these fragments. The M3-M2 internal fragment, generated by cleavages at M3 and M2, is much more sensitive to poly(A)-dependent degradation than the P1-M2 mRNA, which exhibits the same 3' end as M3-M2 but harbours the 5' end of the primary transcript. We conclude that 5' extremities modulate the poly(A)-dependent degradation of mRNA fragments and that the 5' cleavage by RNase E at M3 activates the chemical degradation of the rpsO mRNA.
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PMID:E. coli RpsO mRNA decay: RNase E processing at the beginning of the coding sequence stimulates poly(A)-dependent degradation of the mRNA. 1004 80

Poly(A) tails in Escherichia coli are hypothesized to provide unstructured single-stranded substrates that facilitate the degradation of mRNAs by ribonucleases. Here, we have investigated the role that such nucleases play in modulating polyadenylation in vivo by measuring total poly(A) levels, polyadenylation of specific transcripts, growth rates and cell viabilities in strains containing various amounts of poly(A) polymerase I (PAP I), polynucleotide phosphorylase (PNPase), RNase II and RNase E. The results demonstrate that both PNPase and RNase II are directly involved in regulating total in vivo poly(A) levels. RNase II is primarily responsible for degrading poly(A) tails associated with 23S rRNA, whereas PNPase is more effective in modulating the polyadenylation of the lpp and 16S rRNA transcripts. In contrast, RNase E appears to affect poly(A) levels indirectly through the generation of new 3' termini that serve as substrates for PAP I. In addition, whereas excess PNPase suppresses polyadenylation by more than 70%, the toxicity associated with increased poly(A) levels is not reduced. Conversely, toxicity is significantly reduced in the presence of excess RNase II. Overproduction of RNase E leads to increased polyadenylation and no reduction in toxicity.
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PMID:Polynucleotide phosphorylase, RNase II and RNase E play different roles in the in vivo modulation of polyadenylation in Escherichia coli. 1084 84

From the fresh sclerotia of the mushroom Pleurotus tuber-regium, a potent homodimeric ribonuclease exhibiting a molecular weight of 29 kDa in FPLC-gel filtration and sodium dodecyl sulfate-polyacrylamide gel electrophoresis was isolated. The protein was unadsorbed on DEAE-cellulose and adsorbed on Affi-gel blue gel, CM-cellulose and Mono S. It manifested strong ribonucleolytic activity toward Poly G, slight activity toward Poly U and Poly A, and minimal activity toward Poly C. Its optimal pH was determined to be 6.5 when yeast transfer RNA was used as substrate. Its ribonucleolytic activity was resistant to heating at 100 degrees C for 30 min but was inhibited by a number of salts. The protein inhibited cell-free translation in a rabbit reticulocyte lysate with an IC50 of 0.09 nM. Three out of the four amino acid residues at the active site (positions 38-41) of P. ostreatus ribonuclease, YNNF, were also found at positions 17-20 in the P. tuber-regum RNase. However, unlike P. ostreatus RNase, no cysteine residues were detected in the N-terminal sequence.
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PMID:Purification and characterization of a potent homodimeric guanine-specific ribonuclease from fresh mushroom (Pleurotus tuber-regium) sclerotia. 1133 Dec 3

Poly(A)-specific ribonuclease (PARN) is an oligomeric, processive, and cap-interacting 3' exonuclease. We have studied how the m7G(5')ppp(5')G cap structure affects the activity of PARN. It is shown that the cap has four distinct effects: (i) It stimulates the rate of deadenylation if provided in cis; (ii) it inhibits deadenylation if provided at high concentration in trans; (iii) it stimulates deadenylation if provided at low concentration in trans; and (iv) it increases the processivity of PARN when provided in cis. It is shown that the catalytic and cap binding sites on PARN are separate. The important roles of the 7-methyl group and the inverted guanosine residue of the cap are demonstrated. An active deadenylation complex, consisting of the poly(A)-tailed RNA substrate and PARN, has been identified. Complex formation does not require a cap structure on the RNA substrate. The multiple effects of cap are all accounted for by a simple, kinetic model that takes the processivity of PARN into account.
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PMID:The mRNA cap structure stimulates rate of poly(A) removal and amplifies processivity of degradation. 1135 75

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