EC:3.1.26.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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 small protein (VPg) covalently linked to the 5' end of poliovirus Type 1 (PV-1) RNA has been labeled in vitro with 125I using the Bolton and Hunter reagent. The RNA is not degraded under the conditions used and nearly all the label enters VPg and not the poly-nucleotide chain. When this 125I-labeled RNA is cleaved with RNase III at low monovalent salt concentrations, one major 125I-labeled fragment, approximately 100 nucleotides long, is produced. The corresponding fragment from similar digests of 32P-labeled RNA has also been identified. The 32P-labeled fragment changes electrophoretic mobility after protease treatment indicating that it contains VPg. Furthermore, the RNase T1 oligonucleotide known to be at the 5' terminus of poliovirus RNA is found in T1 digests of the purified fragment. These results confirm that the fragment is derived from the 5' end of the RNA. This fragment will be useful in studies concerning the initiation of protein synthesis during poliovirus infection.
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PMID:Identification of specific fragments containing the 5' end of poliovirus RNA after ribonuclease III digestion. 21 65

Double-stranded RNAs from Penicillium chrysogenum virus have been treated with RNAse III, pancreatic RNAse A and RNAse T1 and the degradation of the RNAs has been studied under different conditions. It was found that only the two former enzymes cut across both strands, RNase T1 cannot cleave double strands. RNase III was shown to digest double-stranded RNA by a two step process: an initial phase of specific cleavage is followed by random degradation. In the first phase the enzyme exhibited a definite preference for some specific base pattern. Partial or complete degradation with pancreatic RNase A could also be achieved in media with high salt concentration provided that the enzyme: substrate ratio was increased together with the salt concentration. By combining different assay techniques, the process of degradation was followed from the early stages to complete digestion and the breakdown products were characterised. It is suggested that a structural change in the enzyme molecules enables them to act on double-stranded RNA. RNAse T1, being unable to cleave double strands, provides a useful tool for studying the secondary structure of RNA molecules. Treatment with different nucleases yielded some new information on the structure of different RNA species in Penicillium stoloniferum virus.
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PMID:Action of nucleases on double-stranded RNA. 81 98

The 30 S ribosomal precursor RNA has been prepared from Escherichia coli AB301/105 (RNase III-) labeled with 32-PO4 in the presence of chloramphenicol. Direct nucleotide sequence studies yield the following information. 1. The major 5'-terminal sequence in our precursor preparations is pppA-C-U-G-. 2. Treatment of the precursor RNA with purified ribonuclease III in vitro releases species sedimenting near 23 S and 17 S, neither of which retain the pppA- end, plus a collection of small fragments with chain lengths of less than 400 nucleotides. 3. The RNase III product sedimenting near 17 S (16 SIII) appears identical with the 17 S RNA typically isolated from pulse-labeled or chloramphenicol-treated cells or from several mutants deficient in ribosome assembly: fingerprint analysis reveals the presence of the same additional RNase T1 oligonucleotides and the 5' terminus (pU-G-) previously described for 17 S RNA. A 3'-terminal T1 oligonucleotide (which was not previously identifiable in the case of the 17 S precursor) has been isolated from 16 S III and its sequence determined: C-U-C-A-C-A-C-A. 4. 5 S rRNA sequences are contained in an RNase III-released fragment of approximately 300 nucleotides. This molecule lacks the 5' terminus of the mature 5 S RNA. The implications of these findings with respect to the control of ribosomal RNA synthesis, the pathways of rRNA processing in vivo, and the specificity of RNase III cleavage of natural substrates are discussed.
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PMID:The 30 S ribosomal precursor RNA from Escherichia coli. A primary transcript containing 23 S, 16 S, and 5 S sequences. 109 85

A role for the Epstein-Barr virus small RNA species EBER-1 in the regulation of protein synthesis has been investigated in the reticulocyte-lysate cell-free translation system. Recombinant EBER-1 was synthesized by in vitro transcription of a plasmid containing the viral gene and purified by CF11-cellulose chromatography and ribonuclease III treatment. When added to the reticulocyte lysate at 10-20 micrograms/ml or more, EBER-1 prevents the inhibition of protein synthesis caused by low concentrations of synthetic double-stranded RNA, poly(I).poly(C). This effect is eliminated by treatment of the recombinant EBER-1 with ribonuclease T1. Disruption of the secondary structure of EBER-1 by substitution of inosine for guanosine in the in-vitro-synthesized RNA impairs the ability of EBER-1 to prevent the poly(I).poly(C)-mediated inhibition of protein synthesis. These results suggest that high concentrations of EBER-1 regulate protein synthesis by blocking the activation of the double-stranded RNA-dependent eukaryotic initiation factor 2 alpha (eIF-2 alpha) protein kinase DAI (p68), and that this property is dependent on the secondary structure of the small RNA molecule.
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PMID:Translational control by the Epstein-Barr virus small RNA EBER-1. Reversal of the double-stranded RNA-induced inhibition of protein synthesis in reticulocyte lysates. 217 60

Bacteriophage lambda transcripts were synthesized in vitro using lambda b2 DNA and Escherichia coli RNA polymerase. RNA molecules initiating with ATP were labeled exclusively at the 5'-end by transcribing in the presence of [gamma-32P]ATP. They were analyzed by electrophoresis in 3.5% polyacrylamide, 7.5 M urea gels followed by autoradiography. The previously known 6 S rho-independent transcript and rho-dependent 9 S and 8 S transcripts were observed. A new rho-dependent 5 S transcript was also detected. The 5 S RNA was not the result of cleavage of larger RNAs by ribonuclease III. Analysis of partial ribonuclease T1 digestion products of isolated 5'-end-labeled transcripts showed that the 5 S RNA is synthesized from promoter pR, the promoter for the 9 S and 8 S RNA species. A similar analysis of transcripts labeled with 32P exclusively at the 3'-terminus by the post-transcriptional addition of a [32P]pCp moiety with T4 RNA ligase revealed the positions of guanosine nucleotides proximal to the 3'-hydroxyl end. This information, and inspection of the known DNA nucleotide sequence downstream from pr, allowed us to conclude that the 5 S RNA is a mixture of molecules 112 and 113 nucleotides long terminating in the middle of gene cro. The nucleotide sequence at the 3'-end of the 5 S RNA is similar to that of other rho-dependent transcripts and lacks the oligo(U) found at the terminus of rho-independent transcripts.
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PMID:Characterization of a rho-dependent termination site within the cro gene of bacteriophage lambda. 644 59

We studied the distribution of repetitive sequence elements capable of forming double-stranded regions in nuclear RNA of HeLa, KB, and L cells. In human RNA populations, we called these regions duplex Alu family RNA (dAfRNA) because they represent transcripts of the highly reiterated family of DNA regions known as "Alu family DNA" (Rubin et al., Nature (London) 284:372-374, 1980). Although the dAfRNA populations of both human cell lines (HeLa and KB) have low sequence complexity, they represent 5% of the total heterogeneous nuclear RNA and have identical fingerprints; mouse L-cell dAf-like RNA (which has a similar complexity) represents only 2% of the total heterogeneous nuclear RNA and has an entirely different fingerprint. We utilized Escherichia coli RNase III as a highly specific reagent for the recognition of RNA:RNA duplex structure. This enzyme cleaves within the six characteristic RNase T1-resistant oligonucleotides of HeLa- and KB-cell dAfRNA (Robertson et al., J. Mol. Biol. 115:571-589, 1977). In addition, the size of heterogeneous nuclear RNA from all three cell types is reduced from greater than 32S to about 15S after RNase III treatment. We conclude that this size shift is a result of cleavage within dAfRNA regions and that such regions are present in most or all of the large RNA transcripts of these cells.
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PMID:Structure and distribution of Alu family sequences or their analogs within heterogeneous nuclear RNA of HeLa, KB, and L cells. 670 May 93

In Escherichia coli, rRNA operons are transcribed as 30S precursor molecules that must be extensively processed to generate mature 16S, 23S and 5S rRNA. While it is known that RNase III cleaves the primary transcript to separate the individual rRNAs, there is little information about the secondary processing reactions needed to form their mature 3' and 5' termini. We have now found that inactivation of the endoribonuclease RNase E slows down in vivo maturation of 16S RNA from the 17S RNase III cleavage product. Moreover, in the absence of CafA protein, a homolog of RNase E, formation of 16S RNA also slows down, but in this case a 16.3S intermediate accumulates. When both RNase E and CafA are inactivated, 5' maturation of 16S rRNA is completely blocked. In contrast, 3' maturation is essentially unaffected. The 5' unprocessed precursor that accumulates in the double mutant can be assembled into 30S and 70S ribosomes. Precursors also can be processed in vitro by RNase E and CafA. These data indicate that both RNase E and CafA protein are required for a two step, sequential maturation of the 5' end of 16S rRNA, and that CafA protein is a new ribonuclease. We propose that it be renamed RNase G.
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PMID:RNase G (CafA protein) and RNase E are both required for the 5' maturation of 16S ribosomal RNA. 1032 33

RNase R is an important exoribonuclease involved in the maturation and degradation of RNA. RNase R is co-transcribed with other genes in the same operon. In this report, we show that under physiological conditions maturation of these co-transcripts and the levels of RNase R are mainly dependent on the endoribonuclease RNase E. The presence of the full-length RNase E is necessary for the decay of intermediary products that arise from the maturation of transcripts from the rnr operon. RNase G and RNase III do not seem to have a primary role in the processing of the rnr transcripts. However, the accumulation of intermediary transcripts in an rng mutant suggests that RNase G may act in the degradation of the transcripts already cleaved by RNase E. These results demonstrated that other ribonucleases can act as an additional level of regulation in the control of the expression of RNase R.
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PMID:The role of endoribonucleases in the regulation of RNase R. 1656 45

In pathogenic bacteria, a large number of sRNAs coordinate adaptation to stress and expression of virulence genes. To better understand the turnover of regulatory sRNAs in the model pathogen, Salmonella typhimurium, we have constructed mutants for several ribonucleases (RNase E, RNase G, RNase III, PNPase) and Poly(A) Polymerase I. The expression profiles of four sRNAs conserved among many enterobacteria, CsrB, CsrC, MicA and SraL, were analysed and the processing and stability of these sRNAs was studied in the constructed strains. The degradosome was a common feature involved in the turnover of these four sRNAs. PAPI-mediated polyadenylation was the major factor governing SraL degradation. RNase III was revealed to strongly affect MicA decay. PNPase was shown to be important in the decay of these four sRNAs. The stability of CsrB and CsrC seemed to be independent of the RNA chaperone, Hfq, whereas the decay of SraL and MicA was Hfq-dependent. Taken together, the results of this study provide initial insight into the mechanisms of sRNA decay in Salmonella, and indicate specific contributions of the RNA decay machinery components to the turnover of individual sRNAs.
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PMID:Characterization of the role of ribonucleases in Salmonella small RNA decay. 1798 74

Replication of the ColE2 plasmid requires a plasmid-coded initiator protein (Rep). Rep expression is controlled by antisense RNA (RNAI) against the Rep mRNA at a translational step. In this paper, we examined the effects of host RNA degradation enzymes on the degradation process of the Rep mRNA and its degradation intermediates especially those carrying the 5' untranslated region. We showed that the Rep mRNA is subjected to complex degradation pathways involving at least RNase I, RNase II, RNase III, RNase E, RNase G and PNPase. RNase II acts as a major exoribonuclease and PNPase plays a minor role. We also showed that the PcnB (polyA polymerase I) plays only a minor role in the Rep mRNA degradation process. The RNA degradation pathways of the Rep mRNA and RNAI of the ColE2 plasmid are quite different. Based on these results, we speculate that the ColE2 Rep mRNA and RNAI are endowed with individual RNA half lives required for the efficient copy number control by being subjected to different RNA degradation systems.
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PMID:Replication initiator protein mRNA of ColE2 plasmid and its antisense regulator RNA are under the control of different degradation pathways. 1819 Dec 5

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