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)

RNase D was recently reported as a new enzymatic activity associated with HIV-1 reverse transcriptase (RT), cleaving RNA at two positions within the double-stranded region of the tRNA primer-viral RNA template complex (Ben-Artzi et al., Proc. Natl. Acad. Sci. USA 89 (1992) 927-931). This would make RNase D a fourth distinct activity of HIV-1 RT, in addition to RNA- and DNA-dependent DNA polymerase and RNase H. Using a specific substrate containing tRNA(Lys,3) hybridized to the primer binding site, we were able to detect the reported RNase D activity in our preparations of recombinant HIV-1 RT. This activity was also present in several active-site mutants of RT, suggesting that it is independent of the RNase H and polymerase functionalities of RT. Furthermore, we found that the cleavage specificity of RNase D is the same as that of RNase III isolated from E.coli. A likely explantation of these results--that the observed RNase D activity is attributable to traces of RNase III contamination--was further strengthened by the finding that the recombinant preparations of HIV-1 RT can specifically cleave a phage T7-derived double-stranded RNA processing signal, which has been used as a model substrate for detection of E.coli RNase III. Moreover, RT purified from an RNase III- strain of E.coli displayed no cleavage of the tRNA primer-RNA template complex.
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PMID:RNase D, a reported new activity associated with HIV-1 reverse transcriptase, displays the same cleavage specificity as Escherichia coli RNase III. 128 Aug 10

The aphid Schizaphis graminum is dependent on an association with a prokaryotic endosymbiont (Buchnera aphidicola). The nucleotide (nt) sequence of a 5040 base pair (bp) DNA fragment of B. aphidicola, homologous to the rplL-rpoB-rpoC portion of the Escherichia coli beta operon, was determined. The DNA coded for the terminal 35 amino acids of RplL (large ribosomal subunit protein L7/L12), the complete RpoB (beta-subunit of RNA polymerase), and the first 209 amino acids of RpoC (beta'-subunit of RNA polymerase). The deduced sequences of B. aphidicola RplL, RpoB, and RpoC were 71, 84, and 91% identical, respectively, to the homologous proteins of E. coli. The sequences of two portions of the intergenic region between rplL and rpoB were nearly identical in both B. aphidicola and E. coli. One sequence constituted an inverted repeat that could be an RNase III-messenger RNA processing site; the other sequence preceded RpoB. A compilation of the codon usage for RpoB, RpoC, and other B. aphidicola proteins indicated a major preference for A or T in the first and third positions, a result consistent with the low guanine plus cytosine (G + C) content of the DNA of this organism.
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PMID:Sequence analysis of an aphid endosymbiont DNA fragment containing rpoB (beta-subunit of RNA polymerase) and portions of rplL and rpoC. 136 99

The primary transcript of pnp, the gene encoding polynucleotide phosphorylase in Escherichia coli, is processed in the 5' end region by ribonuclease III (RNase III). The unprocessed transcript shows enhanced stability compared with the processed transcript. We report here that, unlike the processed transcript, the unprocessed pnp transcript did not accept endonucleolytic attack at, at least, five cleavage sites. Sequencing analysis of the four cleavage products shows no sequence specific to all these sites, but AU rich stretches were observed at three sites.
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PMID:Processing in the 5' region of the pnp transcript facilitates the site-specific endonucleolytic cleavages of mRNA. 137 67

The replication frequency of plasmid R1 is regulated by an antisense RNA, CopA, which inhibits the synthesis of the rate-limiting initiator protein RepA. The inhibition requires an interaction between the antisense RNA and its target, CopT, in the leader of the RepA mRNA. This binding reaction has previously been studied in vitro, and the formation of a complete RNA duplex between the two RNAs has been demonstrated in vitro and in vivo. Here we investigate whether complete duplex formation is required for CopA-mediated inhibition in vivo. A mutated copA gene was constructed, encoding a truncated CopA which is impaired in its ability to form a complete CopA/CopT duplex, but which forms a primary binding intermediate (the 'kissing complex'). The mutated CopA species (S-CopA) mediated incompatibility against wild-type R1 plasmids and inhibited RepA-LacZ fusion protein synthesis. Northern blot, primer extension and S1 analyses indicated that S-CopA did not form a complete duplex with CopT in vivo since bands corresponding to RNase III cleavage products were missing. An in vitro analysis supported the same conclusion. These data suggest that formation of the 'kissing complex' suffices to inhibit RepA synthesis, and that complete CopA/CopT duplex formation is not required. The implications of these findings are discussed.
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PMID:Replication control in plasmid R1: duplex formation between the antisense RNA, CopA, and its target, CopT, is not required for inhibition of RepA synthesis. 137 49

1. A precursor to small stable RNA, 10Sa RNA, accumulates in large amounts in a temperature sensitive RNase E mutant at non-permissive temperatures, and somewhat in an rnc (RNase III-) mutant, but not in an RNase P- mutant (rnp) or wild type E. coli cells. 2. Since p10Sa RNA was not processed by purified RNase E and III in customary assay conditions, we purified p10Sa RNA processing activity about 700-fold from wild type E. coli cells. 3. Processing of p10Sa RNA by this enzyme shows an absolute requirement for a divalent cation with a strong preference for Mn2+ over Mg2+. Other divalent cations could not replace Mn2+. 4. Monovalent cations (NH+4, Na+, K+) at a concentration of 20 mM stimulated the processing of p10Sa RNA and a temperature of 37 degrees C and pH range of 6.8-8.2 were found to be optimal. 5. The enzyme retained half of its p10Sa RNA processing activity after 30 min incubation at 50 degrees C. 6. Further characterization of this activity indicated that it is RNase III. 7. To further confirm that the p10Sa RNA processing activity is RNase III, we overexpressed the RNase III gene in an E. coli cells that lacks RNase III activity (rnc mutant) and RNase III was purified using one affinity column, agarose.poly(I).poly(C). 8. This RNase III preparation processed p10Sa RNA in a similar way as observed using the p10Sa RNA processing activity purified from wild type E. coli cells, confirming that the first step of p10Sa RNA processing is carried out by RNase III.
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PMID:Characterization of the RNA processing enzyme RNase III from wild type and overexpressing Escherichia coli cells in processing natural RNA substrates. 137 63

Characterization of the maturation of precursor 10Sa RNA revealed that RNase III processed p10Sa RNA to two intermediate molecules. We showed that the intermediates are not conformers and both are larger than the mature 10Sa RNA. Cell extracts further process the RNase III products to an RNA molecule which has a different conformation than 10Sa RNA but is approximately the same size as 10Sa RNA. An inhibitor of p10Sa RNA processing by RNase III was identified. It is a protein, with a molecular mass of approximately 17 kDa.
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PMID:10Sa RNA: processing by and inhibition of RNase III. 137 35

The hok/sok, srnB and pnd systems of plasmids R1, F and R438 mediate plasmid maintenance by killing plasmid-free segregants. The systems encode exceptionally stable full-length mRNAs that code for potent cell toxins that kill the cells from within. The systems also produce truncated mRNAs whose appearance is correlated with killing activity. The truncated mRNAs are shortened by 35 to 70 nucleotides in the 3' ends, but have the same 5' ends as the full-length transcripts. Translation of the stable killer mRNAs is regulated by unstable antisense RNAs that are complementary to the leader regions of the full-length and truncated mRNAs. We show here, that both the presence of the antisense RNA and of the host enzyme RNase III is required for rapid cleavage of the truncated mRNAs, and we map the cleavage point in the Hok mRNA in vitro and in vivo to be located between nucleotides +245 and +246. The RNase III cleavage products of the Hok mRNA were found to be very unstable in vivo. Thus, RNase III cleavage seems to be the initial event leading to decay of the killer mRNAs. In an rnc- strain, the truncated mRNA species were found in steady-state cells. This observation indicates that the truncated mRNAs are formed constitutively and independently of the presence of the antisense RNAs. Thus, the antisense RNAs prevent the accumulation of the truncated mRNAs solely by mediating their rapid hydrolysis by RNase III. Furthermore, the generation of the truncated killer mRNAs in the rnc- host indicate that RNase III is dispensable for induction of the killer gene systems. Based on these and on observations obtained previously, we present a molecular model that explains the activation of the killer mRNAs in plasmid-free segregants and after addition of rifampicin.
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PMID:Mechanism of killer gene activation. Antisense RNA-dependent RNase III cleavage ensures rapid turn-over of the stable hok, srnB and pndA effector messenger RNAs. 138 May 62

We have identified a double-stranded (ds)RNA-binding domain in each of two proteins: the product of the Drosophila gene staufen, which is required for the localization of maternal mRNAs, and a protein of unknown function, Xlrbpa, from Xenopus. The amino acid sequences of the binding domains are similar to each other and to additional domains in each protein. Database searches identified similar domains in several other proteins known or thought to bind dsRNA, including human dsRNA-activated inhibitor (DAI), human trans-activating region (TAR)-binding protein, and Escherichia coli RNase III. By analyzing in detail one domain in staufen and one in Xlrbpa, we delimited the minimal region that binds dsRNA. On the basis of the binding studies and computer analysis, we have derived a consensus sequence that defines a 65- to 68-amino acid dsRNA-binding domain.
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PMID:A conserved double-stranded RNA-binding domain. 143 2

To assess the involvement of the RNA cleavage site-proximal 2' hydroxyl group in the RNase III catalytic mechanism, a specific processing substrate was chemically synthesized to contain a 2'-deoxyribose residue at the scissile phosphodiester bond. The RNA substrate, corresponding to the phage T7 R1.1 primary processing signal, can be accurately cleaved in vitro by RNase III. A fully deoxyribose-substituted R1.1 processing signal is not cleaved by RNase III, nor does it in excess inhibit cleavage of unmodified substrate. These results show that the 2' hydroxyl group proximal to the scissile bond is not an essential participant in the RNase III processing reaction; however, other 2' hydroxyl groups are important for substrate reactivity, and may be involved in establishing proper double helical conformation, and/or specific substrate contacts with RNase III.
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PMID:Accurate enzymatic cleavage in vitro of a 2'-deoxyribose-substituted ribonuclease III processing signal. 153 83

It has been previously shown that the pnp messenger RNAs are cleaved by RNase III at the 5' end and that these cleavages induce a rapid decay of these messengers. A translational fusion between pnp and lacZ was introduced into the chromosome of a delta lac strain to study the expression of pnp. In the presence of increased cellular concentrations of polynucleotide phosphorylase, the level of the hybrid beta-galactosidase is repressed, whereas the synthesis rate of the corresponding message is not significantly affected. In the absence of pnp, the level of the hybrid protein increases strongly. Thus, polynucleotide phosphorylase is post-transcriptionally autocontrolled. However, autocontrol is totally abolished in strains where the RNase III site on the pnp message has been deleted or in strains devoid of RNase III. These results suggest that polynucleotide phosphorylase requires RNase III cleavages to autoregulate the translation of its message. Other mutations in the ribosome binding site region support the hypothesis that this 3' to 5' processive enzyme could recognize a specific repressor binding site at the 5' end of pnp mRNA. Implications of these results on the mechanism of regulation and on messenger degradation are discussed.
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PMID:E.coli polynucleotide phosphorylase expression is autoregulated through an RNase III-dependent mechanism. 162 24

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