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Query: EC:3.1.13.1 (exoribonuclease)
 732 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Examination of double mutants lacking one of the exoribonucleases, RNase II, RNase D, RNase BN, or RNase R, and also devoid of tRNA nucleotidyltransferase has suggested that none of these RNases participates in the end-turnover of tRNA. This prompted a search for and identification of a new exoribonuclease, termed RNase T. RNase T could be detected in mutant Escherichia coli strains lacking as many as three of the known exoribonucleases, and it could be separated from each of the four previously described RNases. RNase T is optimally active at pH 8-9 and requires a divalent cation for activity. The enzyme is sensitive to ionic strengths greater than 50 mM and is rapidly inactivated by heating at 45 degrees C. Its preferred substrate is tRNA-C-C-[14C]A, with much less activity shown against tRNA-C-C. RNase T is an exoribonuclease that initiates attack at the 3' hydroxyl terminus of tRNA and releases AMP in a random mode of hydrolysis. The possible involvement of RNase T in end-turnover of tRNA and in RNA metabolism in general are discussed.
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PMID:Ribonuclease T: new exoribonuclease possibly involved in end-turnover of tRNA. 637 42

We have used an in vitro Escherichia coli tRNA processing system to investigate the specific role of individual exoribonucleases in the 3' maturation of tRNA precursors. The processing of pre-tRNA(Tyr)su3+ and pre-tRNA(2Arg) was studied using extracts from cells lacking one or multiple exoribonucleases or using purified RNases. Earlier genetic studies had suggested that multiple exoribonucleases contributed to the maturation of tRNA precursors, and this was proven directly in the studies described here. Complete 3' processing required the combined action of multiple exoribonucleases, and each RNase showed distinct specificities for maturation of the different parts of the 3' precursor segment. RNase II and polynucleotide phosphorylase were most effective in shortening long 3' trailer sequences to intermediates with 2-4 extra 3' residues. Final trimming of the last few 3' nucleotides of these precursors was carried out most efficiently by RNases T and PH, but the two enzymes differed in their specificity for individual nucleotide positions. Depending on the tRNA precursor, the relative importance of the various RNases to the overall maturation process differed. We also showed that purified exoribonucleases can completely complement mutant extracts and that tRNA maturation can be totally reconstructed in vitro using purified enzymes. These studies provide the first detailed information about the specific role of individual exoribonucleases in tRNA processing, and bring us closer to defining a complete E. coli tRNA maturation pathway.
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PMID:The role of individual exoribonucleases in processing at the 3' end of Escherichia coli tRNA precursors. 750 97

The maturation of 5S RNA in Escherichia coli is poorly understood. Although it is known that large precursors of 5S RNA accumulate in mutant cells lacking the endoribonuclease-RNase E, almost nothing is known about how the mature 5' and 3' termini of these molecules are generated. We have examined 5S RNA maturation in wild-type and single- or multiple-exoribonuclease-deficient cells by Northern blot and primer-extension analysis. Our results indicate that no mature 5S RNA is made in RNase T-deficient strains. Rather, 5S RNA precursors containing predominantly 2 extra nucleotides at the 3' end accumulate. Apparently, these 5S RNAs are functional inasmuch as mutant cells are viable, growing only slightly slower than wild type. Purified RNase T can remove the extra 3' residues, showing that it is directly involved in the trimming reaction. In contrast, mutations affecting other 3' exoribonucleases have no effect on 5S RNA maturation. Approximately 90% of the 5S RNAs in both wild-type and RNase T- cells contain mature 5' termini, indicating that 5' processing is independent of RNase T action. These data identify the enzyme responsible for generating the mature 3' terminus of 5S RNA molecules and also demonstrate that a completely processed 5S RNA molecule is not essential for cell survival.
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PMID:The tRNA processing enzyme RNase T is essential for maturation of 5S RNA. 754 80

Our knowledge of the 3' processing of tRNA precursors is severely limited. Although six exoribonucleases able to act on Escherichia coli tRNA precursors in vitro have been identified, their involvement in tRNA maturation in vivo has not been demonstrated. Here we show, using a wide range of multiple RNase-deficient strains and a quantitative suppression assay, that at least five of these enzymes--RNase II, RNase D, RNase BN, RNase T, and RNase PH--can participate in the synthesis of functional tRNA(Tyr)su+3 in vivo. Moreover, any one of the five RNases is sufficient to allow tRNA processing to proceed although with varying effectiveness. Examination of the level of aminoacylation of tRNA isolated from RNase-deficient strains suggested that tRNA precursors accumulate in the most defective cells. These data indicate that exoribonucleases are required for tRNA maturation in vivo and that there is a high degree of functional overlap among the enzymes. These studies contribute to the identification of all the enzymes necessary for defining the complete processing pathway for E. coli tRNA precursors.
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PMID:Multiple exoribonucleases are required for the 3' processing of Escherichia coli tRNA precursors in vivo. 842 61

Hammerhead ribozymes are small catalytic RNA molecules that can be designed to specifically cleave other RNAs. These ribozymes have exhibited low efficiency when examined inside cells, perhaps in part because of their sensitivity to intracellular RNases. In an effort to better understand intracellular degradation of small, foreign RNAs and to develop more stable ribozymes, the ability of Escherichia coli RNase mutants to digest ribozymes was examined. In soluble extracts, most (80 to 90%) of the endonucleolytic activity was due to RNases I and I*, since degradative activity was inhibited by Mg2+ and by the rna-2 mutation. Degradation by exonucleolytic activities was temperature sensitive in extracts from an rna pnp rnb(Ts) triple mutant but not in extracts from an rna rnb(Ts) double mutant. Thus, the products of rnb and pnp, RNase II and polynucleotide phosphorylase, respectively, appear to be the major exonucleases that degrade hammerhead ribozymes. Examination of intracellular degradation revealed that RNases I and I* contributed to about half of the degradative activity as judged by comparison of the rate of ribozyme decay in wild-type and rna-2 mutant cells. Little additional effect was observed in rne(RNase E) and rnc (RNaseIII) mutants. Taken together, these data indicate that hammerhead ribozymes are digested largely by the degradative class of RNase (RNases I, I* and II and polynucleotide phosphorylase).
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PMID:RNases involved in ribozyme degradation in Escherichia coli. 862 92

vacB, a gene previously shown to be required for expression of virulence in Shigella and enteroinvasive Escherichia coli, has been found to encode the 3'-5' exoribonuclease, RNase R. Thus, cloning of E. coli vacB led to overexpression of RNase R activity, and partial deletion or interruption of the cloned gene abolished this overexpression. Interruption of the chromosomal copy of vacB eliminated endogenous RNase R activity; however, the absence of RNase R by itself had no effect on cell growth. In contrast, cells lacking both RNase R and polynucleotide phosphorylase were found to be inviable. These data indicate that RNase R participates in an essential cell function in addition to its role in virulence. The identification of the vacB gene product as RNase R should aid in understanding how the virulence phenotype in enterobacteria is expressed and regulated. On the basis of this information we propose that vacB be renamed rnr.
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PMID:The vacB gene required for virulence in Shigella flexneri and Escherichia coli encodes the exoribonuclease RNase R. 960 4

RNA decay in bacteria is carried out by a number of enzymes that participate in the coordinated degradation of their substrates. Endo- and exonucleolytic cleavages as well as polyadenylation are generally involved in determining the half-life of RNAs. Small, untranslated antisense RNAs are suitable model systems to study decay. A study of the pathway of degradation of CopA, the copy number regulator RNA of plasmid R1, is reported here. Strains carrying mutations in the genes encoding RNase E, polynucleotide phosphorylase (PNPase), RNase II and poly(A) polymerase I (PcnB/PAP I)--alone or in combination--were used to investigate degradation patterns and relative half-lives of CopA. The results obtained suggest that RNase E initiates CopA decay. Both PNPase and RNase II can degrade the major 3'-cleavage product generated by RNase E. This exonucleolytic degradation is aided by PcnB, which may imply a requirement for A-tailing. RNase II can partially protect CopA's 3'-end from PNPase-dependent degradation. Other RNases are probably involved in decay, since in rnb/pnp double mutants, decay still occurs, albeit at a reduced rate. Experiments using purified RNase E identified cleavage sites in CopA in the vicinity of, but not identical to, those mapped in vivo, suggesting that the cleavage site specificity of this RNase is modulated by additional proteins in the cell. A model of CopA decay is presented and discussed.
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PMID:Degradation pathway of CopA, the antisense RNA that controls replication of plasmid R1. 969 24

The ribonuclease active site harbored by the Flp site-specific recombinase can act on two neighboring phosphodiester bonds to yield mechanistically distinct chain breakage reactions. One of the RNase reactions apparently proceeds via a covalent enzyme intermediate and targets the phosphodiester position involved in DNA recombination (Flp RNase I activity). The second activity (Flp RNase II) targets the phosphodiester immediately to the 3' side but appears not to involve an enzyme-linked intermediate. Flp RNase I is absolutely dependent upon Tyr-343 of Flp and is competitive with respect to the normal strand joining reaction. It can utilize the 2'-hydroxyl group from any one of the four ribonucleotides with comparable efficiencies in the cleavage reaction. On the other hand, the RNase II reaction mediated by Flp(Y343F) is specific for U and cannot utilize the 2'-hydroxyl group from ribo-A, -G, or -C under standard reaction conditions. The RNase II activity is also sensitive to the 3'-neighboring base. Although dT is functional, the activity is stimulated by U or U-2'-OMe. The Flp RNase II reaction effectively competes with the normal strand cleavage reaction mediated by Tyr-343, even though their phosphodiester targets are not the same.
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PMID:Flp ribonuclease activities. Mechanistic similarities and contrasts to site-specific DNA recombination. 980 30

In this study, we have used multiple strategies to characterize the mechanisms of the type I and type II RNA cleavage activities harbored by the Flp (pronounced here as "flip") site-specific DNA recombinase (Flp-RNase I and II, respectively). Reactions using half-sites pre-bound by step-arrest mutants of Flp agree with a "shared active site" being responsible for the type I reaction (as is the case with normal DNA recombination). In a "pre-cleaved" type I substrate containing a 3'-phosphotyrosyl bond, the Flp-RNase I activity can be elicited by either wild type Flp or by Flp(Y343F). Kinetic analyses of the type I reaction are consistent with the above observations and support the notion that the DNA recombinase and type I RNase active sites are identical. The type II RNase activity is expressed by Flp(Y343F) in a half-site substrate and is unaffected by the catalytic constitution of a Flp monomer present on a partner half-site. Reaction conditions that proscribe the assembly of a DNA bound Flp dimer have no effect on Flp-RNase II. These biochemical results, together with kinetic data, are consistent with the reaction being performed from a "non-shared active site" contained within a single Flp monomer. The Flp-related recombinase Cre, which utilizes a non-shared recombination active site, exhibits the type I RNA cleavage reaction. So far, we have failed to detect the type II RNase activity in Cre. Despite their differences in active site assembly, Cre functionally mimics Flp in being able to provide two functional active sites from a trimer of Cre bound to a three-armed (Y-shaped) substrate.
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PMID:Biochemical and kinetic analysis of the RNase active sites of the integrase/tyrosine family site-specific DNA recombinases. 1158 26

Escherichia coli RNase R, a 3' --> 5' exoribonuclease homologous to RNase II, was overexpressed and purified to near homogeneity in its native untagged form by a rapid procedure. The purified enzyme was free of nucleic acid. It migrated upon gel filtration chromatography as a monomer with an apparent molecular mass of approximately 95 kDa, in close agreement with its expected size based on the sequence of the rnr gene. RNase R was most active at pH 7.5-9.5 in the presence of 0.1-0.5 mm Mg(2+) and 50-500 mm KCl. The enzyme shares many catalytic properties with RNase II. Both enzymes are nonspecific processive ribonucleases that release 5'-nucleotide monophosphates and leave a short undigested oligonucleotide core. However, whereas RNase R shortens RNA processively to di- and trinucleotides, RNase II becomes more distributive when the length of the substrate reaches approximately 10 nucleotides, and it leaves an undigested core of 3-5 nucleotides. Both enzymes work on substrates with a 3'-phosphate group. RNase R and RNase II are most active on synthetic homopolymers such as poly(A), but their substrate specificities differ. RNase II is more active on poly(A), whereas RNase R is much more active on rRNAs. Neither RNase R nor RNase II can degrade a complete RNA-RNA or DNA-RNA hybrid or one with a 4-nucleotide 3'-RNA overhang. RNase R differs from RNase II in that it cannot digest DNA oligomers and is not inhibited by such molecules, suggesting that it does not bind DNA. Although the in vivo function of RNase R is not known, its ability to digest certain natural RNAs may explain why it is maintained in E. coli together with RNase II.
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PMID:Purification and characterization of the Escherichia coli exoribonuclease RNase R. Comparison with RNase II. 1194 93


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