EC:3.1.26.3 - FACTA Search

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Query: EC:3.1.26.3 (RNase III)
1,015 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The pac1+ gene of the fission yeast Schizosaccharomyces pombe is essential for viability and its overexpression induces sterility and suppresses mutations in the pat1+ and snm1+ genes. The pac1+ gene encodes a protein that is structurally similar to RNase III from Escherichia coli, but its normal function is unknown. We report here the purification and characterization of the Pac1 protein after overexpression in E. coli. The purified protein is a highly active, double-strand-specific endoribonuclease that converts long double-stranded RNAs into short oligonucleotides and also cleaves a small hairpin RNA substrate. The Pac1 RNase is inhibited by a variety of double- and single-stranded polynucleotides, but polycytidylic acid greatly enhances activity and also promotes cleavage specificity. The Pac1 RNase produces 5'-phosphate termini and requires Mg2+; Mn2+ supports activity but causes a loss of cleavage specificity. Optimal activity was obtained at pH 8.5, at low ionic strength, in the presence of a reducing agent. The enzyme is relatively insensitive to N-ethylmaleimide but is strongly inhibited by ethidium bromide and vanadyl ribonucleoside complexes. The properties of the Pac1 RNase support the hypothesis that it is a eukaryotic homolog of RNase III.
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PMID:Purification and characterization of the Pac1 ribonuclease of Schizosaccharomyces pombe. 871 May 10

Control of RNA turnover is a major, but poorly understood, aspect of gene regulation. In multicellular organisms, progress toward dissecting RNA turnover pathways has been made by defining some cis-acting sequences that function as either regulatory or cleavage targets (J. G. Belasco and G. Brawerman, Control of Messenger RNA Stability, 1993). However, the identification of genes encoding proteins that regulate or cleave target RNAs has been elusive (C. A. Beelman and R. Parker, Cell 81:79-183, 1995); this gap in knowledge has made it difficult to identify additional components of RNA turnover pathways. We have utilized a modified expression cloning strategy to identify a developmentally regulated gene from Drosophila melanogaster that encodes a RNase that we refer to as Clipper (CLP). Significant sequence matches to open reading frames encoding unknown functions identified from the Caenorhabditis elegans and Saccharomyces cerevisiae genome sequencing projects suggest that all three proteins are members of a new protein family conserved from lower eukaryotes to invertebrates. We demonstrate that a member of this new protein family specifically cleaves RNA hairpins and that this activity resides in a region containing five copies of a previously uncharacterized CCCH zinc finger motif. CLP's endoribonucleolytic activity is distinct from that associated with RNase A (P. Blackburn and S. Moore, p. 317-433, in P. D. Boyer, ed., The Enzymes, vol. XV, part B, 1982) and is unrelated to RNase III processing of rRNAs and tRNAs (J. G. Belasco and G. Brawerman, Control of Messenger RNA Stability, 1993, and S. A. Elela, H. Igel, and M. Ares, Cell 85:115-124, 1995). Our results suggest that CLP may function directly in RNA metabolism.
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PMID:Cleavage of RNA hairpins mediated by a developmentally regulated CCCH zinc finger protein. 894 20

The Escherichia coli rnc-era-recO operon encodes ribonuclease III (RNase III; a dsRNA endonuclease involved in rRNA and mRNA processing and decay), Era (an essential G-protein of unknown functions and RecO (involved in the RecF homologous recombination pathway). Expression of the rnc and era genes is negatively autoregulated: RNase III cleaves the rncO 'operator' in the untranslated leader, destabilizing the operon mRNA. As part of a larger effort to understand RNase III and Era structure and function, we characterized rnc operon structure, function and regulation in the closely related bacterium Salmonella typhimurium. Construction of a S typhimurium strain conditionally defective for RNase III and Era expression showed that Era is essential for cell growth. This mutant strain also enabled selection of recombinant clones containing the intact S typhimurium rnc-era-recO operon, whose nucleotide sequence, predicted protein sequence, and predicted rncO RNA secondary structure were all highly conserved with those of E coli. Furthermore, genetic and biochemical analysis revealed that S typhimurium rnc gene expression is negatively autoregulated by a mechanism very similar or identical to that in E coli, and that the cleavage specificities of RNase IIIs.t. and RNase IIIE.c. are indistinguishable with regard to rncO cleavage and S typhimurium 23S rRNA fragmentation in vivo.
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PMID:Structure and regulation of the Salmonella typhimurium rnc-era-recO operon. 915 Aug 81

The Pac1 ribonuclease of Schizosaccharomyces pombe is a member of the RNase III family of double-strand-specific ribonucleases. To examine RNA structural features required for efficient cleavage by the Pac1 RNase, we tested a variety of double-stranded and hairpin RNAs as substrates for the enzyme. The Pac1 RNase required substrates that have a minimal helix length of about 20 base pairs. The enzyme cut both strands of the helix at sites separated by two base pairs. However, Pac1 was also able to make a single-stranded cleavage within an internal bulge of an authentic Escherichia coli substrate at the same site chosen by RNase III. Pac1 efficiently degraded the structurally complex adenovirus VA RNA(I), but was inactive against the short HIV-1 TAR RNA hairpin. These results indicate that the Pac1 RNase prefers straight, perfect helices, but it can tolerate internal bulges that do not distort the helix severely. Like its homologue from Saccharomyces cerevisiae, the Pac1 RNase cleaved at two in vivo RNA processing sites in a hairpin structure in the 3' external transcribed spacer of the S. pombe pre-rRNA, suggesting a role for the enzyme in rRNA maturation.
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PMID:Substrate structure requirements of the Pac1 ribonuclease from Schizosaccharmyces pombe. 932 93

We have undertaken a deletion analysis of the 3' external transcribed spacer (3' ETS) in the pre-rRNA of Saccharomyces cerevisiae. A stem loop structure immediately 3' to the 25 S rRNA region is necessary and sufficient for processing of the 3' ETS. This is believed to be by cotranscriptional cleavage by Rnt1p, the yeast homologue of RNase III. In addition, this stem-loop is required for cleavage of site A3 by RNase MRP and for processing at site B1L, in the 3' region of ITS1. Processing at an upstream site in ITS1, site A2, and at sites in the 5' external transcribed spacer are not affected, even by complete deletion of the 3' ETS. We conclude that processing in the 3' ETS and in ITS1 is coupled. This would constitute a quality control that prevents synthesis of the 5. 8 S rRNA and 5' end maturation of the 25 S rRNA in transcripts which are incomplete due to premature transcription termination.
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PMID:The role of the 3' external transcribed spacer in yeast pre-rRNA processing. 957 Oct 34

Ribosomal RNAs are generally synthesized as long, primary transcripts that must be extensively processed to generate the mature, functional species. In Escherichia coli, it is known that the initial 30S precursor is cleaved during its synthesis by the endonuclease RNase III to generate precursors to the 16S, 23S, and 5S rRNAs. However, despite extensive study, the processes by which these intermediate products are converted to their mature forms are poorly understood. In this article, we describe the maturation of 23S rRNA. Based on Northern analysis of RNA isolated from a variety of mutant strains lacking one or multiple ribonucleases, we show that maturation of the 3' terminus requires the action of RNase T, an enzyme previously implicated in the end turnover of tRNA and in the maturation of small, stable RNAs. Although other exoribonucleases can participate in shortening the 3' end of the initial RNase III cleavage product, RNase T is required for removal of the last few residues. In the absence of RNase T, 23S rRNA products with extra 3' residues accumulate and are incorporated into ribosomes, with only small effects on cell growth. Purified RNase T accurately and efficiently converts these immature ribosomes to their mature forms in vitro, whereas free RNA is processed relatively poorly. In vivo, the processing defect at the 3' end has no effect on 5' maturation, indicating that the latter process proceeds independently. We also find that a portion of the 23S rRNA that accumulates in many RNase T- cells becomes polyadenylated because of the action of poly(A) polymerase I. The requirement for RNase T in 23S rRNA maturation is discussed in relation to a model in which only this enzyme, among the eight exoribonucleases present in E. coli, is able to efficiently remove nucleotides close to the double-stranded stem generated by the pairing of the 5' and 3' termini of most stable RNAs.
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PMID:Maturation of 23S ribosomal RNA requires the exoribonuclease RNase T. 991 73

Citrate transport in Lactococcus lactis biovar diacetylactis (L. diacetylactis) is catalyzed by citrate permease P (CitP), which is encoded by the plasmidic citP gene. Two partial overlapping open reading frames citQ and citR are located upstream of citP. These two genes, together with citP, constitute the citQRPoperon. In this report it was shown that in L. diacetylactis and Escherichia coli, cit mRNA is subject to the same specific cleavages at a complex secondary structure which includes the central region of citQ and the 5'-end of citR. The role of ribonucleases in the fate of the cit mRNA processing was investigated in E. coli RNase mutant strains. The results obtained indicate that both endoribonucleases RNase E and RNase III are involved in the generation of mRNA processed species. RNase E is responsible for the major cleavages detected within citQ and upstream of citR, whereas RNase III cleaves citR within its ribosomal binding site. Preliminary results indicate the existence of a RNaselll-like enzyme in L. diacetylactis. Based on these results, a model for the role of cit mRNA processing in the expression of citP is presented.
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PMID:The role of Escherichia coli RNase E and RNase III in the processing of the citQRP operon mRNA from Lactococcus lactis biovar diacetylactis. 1094 65

The chromosome of pathogenic Neisseriae is peppered by members of an abundant family of small DNA sequences known as Correia elements. These DNA repeats, that we call nemis (for neisseria miniature insertion sequences) can be sorted into two major size classes. Both unit-length (154-158 bp) and internally rearranged (104-108 bp) elements feature long terminal inverted repeats (TIRs), and can potentially fold into robust stem-loop structures. Nemis are (or have been) mobile DNA sequences which generate a specific 2-bp target site duplication upon insertion, and strictly recall RUP, a repeated DNA element found in Streptococcus pneumoniae. The subfamilies of 26L/26R, 26L/27R, 27L/27R and 27L/26R elements, found by wide-genome computer surveys in both the Neisseria meningitidis and the Neisseria gonorrhoeae genomes, originate from the combination of TIRs which vary in length (26-27 bp) as in sequence content (L and R types). In both species, the predominant subfamily is made by the 26L/26R elements. The number of nemis is comparable in the N. meningitidis Z2491 (A serogroup) and the MC58 (B serogroup) strains, but is sharply reduced in the N. gonorrhoeae strain F1090. Consequently, several genes which are conserved in the two pathogens are flanked by nemis DNA in the meningococcus genome only. More than 2/3 of nemis are interspersed with single-copy DNA, and are found at close distance from cellular genes. Both primer extension and RNase protection data lend support to the notion that nemis are cotranscribed with cellular genes and subsequently processed, at either one or both TIRs, by a specific endoribonuclease, which plausibly corresponds to RNase III.
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PMID:Whole-genome organization and functional properties of miniature DNA insertion sequences conserved in pathogenic Neisseriae. 1170 39

RNases III are a family of double-stranded RNA (dsRNA) endoribonucleases involved in the processing and decay of a large number of cellular RNAs as well as in RNA interference. The dsRNA substrates of Saccharomyces cerevisiae RNase III (Rnt1p) are capped by tetraloops with the consensus sequence AGNN, which act as the primary docking site for the RNase. We have solved the solution structures of two RNA hairpins capped by AGNN tetraloops, AGAA and AGUU, using NMR spectroscopy. Both tetraloops have the same overall structure, in which the backbone turn occurs on the 3' side of the syn G residue in the loop, with the first A and G in a 5' stack and the last two residues in a 3' stack. A non-bridging phosphate oxygen and the universal G which are essential for Rnt1p binding are strongly exposed. The compared biochemical and structural analysis of various tetraloop sequences defines a novel family of RNA tetraloop fold with the consensus (U/A)GNN and implicates this conserved structure as the primary determinant for specific recognition of Rnt1p substrates.
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PMID:A novel family of RNA tetraloop structure forms the recognition site for Saccharomyces cerevisiae RNase III. 1174

Bacterial double-stranded RNA-specific RNase III recognizes the A-form of an RNA helix with little sequence specificity. In contrast, baker yeast RNase III (Rnt1p) selectively recognizes NGNN tetraloops even when they are attached to a B-form DNA helix. To comprehend the general mechanism of RNase III substrate recognition, we mapped the Rnt1p binding signal and directly compared its substrate specificity to that of both Escherichia coli RNase III and fission yeast RNase III (PacI). Rnt1p bound but did not cleave long RNA duplexes without NGNN tetraloops, whereas RNase III indiscriminately cleaved all RNA duplexes. PacI cleaved RNA duplexes with some preferences for NGNN-capped RNA stems under physiological conditions. Hydroxyl radical footprints indicate that Rnt1p specifically interacts with the NGNN tetraloop and its surrounding nucleotides. In contrast, Rnt1p interaction with GAAA-capped hairpins was weak and largely unspecific. Certain duality of substrate recognition was exhibited by PacI but not by bacterial RNase III. E. coli RNase III recognized RNA duplexes longer than 11 bp with little specificity, and no specific features were required for cleavage. On the other hand, PacI cleaved long, but not short, RNA duplexes with little sequence specificity. PacI cleavage of RNA stems shorter than 27 bp was dependent on the presence of an UU-UC internal loop two nucleotides upstream of the cleavage site. These observations suggest that yeast RNase IIIs have two recognition mechanisms, one that uses specific structural features and another that recognizes general features of the A-form RNA helix.
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PMID:Evaluation of the RNA determinants for bacterial and yeast RNase III binding and cleavage. 1458 74

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