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)

Using lambda phage clones containing segments of the Escherichia coli K12 chromosome as hybridization probes, we found one gene at 42 min on the E. coli chromosome map, the expression of which was affected by RNase III. The sequence of the DNA fragment containing this gene (gen-165) revealed the presence of an open reading frame encoding a polypeptide of 165 amino acid residues. The amino acid sequence deduced from the nucleotide sequence exhibited a remarkable similarity to that of the human ferritin H chain.
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PMID:Cloning and sequencing of an Escherichia coli K12 gene which encodes a polypeptide having similarity to the human ferritin H subunit. 201 45

Two genes, secE and nusG, situated between the tufB and ribosomal protein rplKAJL operons in the rif region at 90 min on the Escherichia coli chromosome, have been sequenced and characterized. The secE gene encodes a 127-amino-acid-long polypeptide, which is an integral membrane protein essential for protein export (P. J. Schatz, P. D. Riggs, A. Jacq, M. J. Fath, and J. Beckwith, Genes Dev. 3:1035-1044, 1989). The nusG gene encodes a 181-amino-acid-long polypeptide and is involved in transcription antitermination. The protein product of nusG is essential for bacterial viability. The secE-nusG genes are cotranscribed, with transcripts initiated at the PEG promoter and terminated at the Rho-independent terminator in the region of the rplK promoter. The majority of transcripts are processed at a number of sites in the 5' untranslated leader region by RNase III and are possibly also processed by a second unidentified nuclease. The role of transcript processing in the regulation of secE and nusG has not yet been established. The juxtaposition and coregulation of a protein export factor and a transcriptional factor raise questions concerning a functional connection between the two processes.
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PMID:Sequence and transcriptional pattern of the essential Escherichia coli secE-nusG operon. 213 19

The splice junction sequence of td mRNA from T4-infected cells has been determined (5'....GGU-CUA....3') and shown to be identical to that of the RNA ligation product encoded by the cloned gene [Belfort et al. Cell 41 (1985) 375-382]. The RNA processing functions, T4 RNA ligase, T4 polynucleotide kinase, and the host prr gene product appear not to be essential for exon ligation; neither are the host endoribonucleases RNase III, RNase P and RNase E required for intron excision. While these results are consistent with the autocatalytic splicing mechanism demonstrated in vitro [Chu et al. J. Biol. Chem. 260 (1985) 10680-10688], they leave unanswered the question of which protein(s), if any, might stimulate the in vivo reaction. Analysis of the products of the cloned td gene has led to identification of two td-encoded polypeptides, namely a polypeptide corresponding to the exon-I-coding sequence (NH2-TS), and the catalytically active thymidylate synthase (TS). Kinetic and nucleotide sequence data provide evidence that NH2-TS is the product of the primary transcript and that TS is encoded by spliced mRNA. These results suggest that splicing may provide a switch controlling the relative expression of NH2-TS and TS, two proteins with markedly different temporal appearances despite their identical transcriptional and translational start sites.
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PMID:RNA splicing and in vivo expression of the intron-containing td gene of bacteriophage T4. 242 90

Bacteriophage T7 expresses a serine/threonine-specific protein kinase activity during infection of its host, Escherichia coli. The protein kinase (gp0.7 PK), encoded by the T7 early gene 0.7, enhances phage reproduction under sub-optimal growth conditions. It was previously shown that ribosomal protein S1 and translation initiation factors IF1, IF2, and IF3 are phosphorylated in T7-infected cells, and it was suggested that phosphorylation of these proteins may serve to stimulate translation of the phage late mRNAs. Using high-resolution two-dimensional gel electrophoresis and specific immunoprecipitation, we show that elongation factor G and ribosomal protein S6 are phosphorylated following T7 infection. The gel electrophoretic data moreover indicate that elongation factor P is phosphorylated in T7-infected cells. T7 early and late mRNAs are processed by ribonuclease III, whose activity is stimulated through phosphorylation by gp0.7 PK. Specific overexpression and phosphorylation was used to locate the RNase III polypeptide in the standard two-dimensional gel pattern, and to confirm that serine is the phosphate-accepting amino acid. The two-dimensional gels show that the in vivo expression of gp0.7 PK results in the phosphorylation of over 90 proteins, which is a significantly higher number than previous estimates. The protein kinase activities of the T7-related phages T3 and BA14 produce essentially the same pattern of phosphorylated proteins as that of T7. Finally, several experimental variables are analysed which influence the production and pattern of phosphorylated proteins in both uninfected and T7-infected cells.
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PMID:Phosphorylation of elongation factor G and ribosomal protein S6 in bacteriophage T7-infected Escherichia coli. 802 76

Using the technique of integrative mapping with three vectors carrying chromosomal rDNA sequences, one of two rRNA operons of loofah witches' broom (LfWB) phytoplasma was constructed. This is the first complete rRNA operon of a phytoplasma to be reported. The operon has a context of 5'-16S-23S-5S-3' with a tRNA(Ile) gene in the ITS and tRNA(Val) and tRNA(Asn) genes downstream from the 5S rRNA gene. Although the other operon has not been cloned, the DNA sequence of a PCR-amplified product shows that it has no tRNA(Ile) gene in the ITS region. The complete nucleotide sequences of 16S, 23S, and 5S rDNA are 1538, 2864, and 113 bp, respectively. Five -10-like sequences, but no -35 sequences, were found within a 494-bp leader region. There was a TG dinucleotide two nucleotides upstream from each -10-like sequence. The existence of a TG dinucleotide at this position has been reported to enhance the efficiency of a promoter without a -35 region. The regions immediately flanking the 5' and 3' ends of 16S and 23S rDNA can form long basepaired stems that contain sites for processing by RNase III. No obvious sequence for a rho-dependent or rho-independent termination site was found downstream from the tRNA(Asn) gene. The transcription may stop within a pyrimidine-rich region, as has been reported for several polypeptide-encoding genes and rRNA operons of archaeobacteria. The presence of the tRNA genes downstream from the 5S rRNA gene in the rRNA operon of LfWB phytoplasma further supports the hypothesis that phytoplasmas are phylogenetically closer to acholeplasmas than to mycoplasmas. The phylogenetic relatedness of LfWB phytoplasma to other phytoplasmas is discussed on the basis of the nucleotide sequence of rRNA genes and ITS.
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PMID:Organization of ribosomal RNA genes from a Loofah witches' broom phytoplasma. 1124 69

Escherichia coli ribonuclease III (EC 3.1.24) is a double-strand- (ds-) specific endoribonuclease involved in the maturation and decay of cellular, phage, and plasmid RNAs. RNase III is a homodimer and requires Mg(2+) to hydrolyze phosphodiesters. The RNase III polypeptide contains an N-terminal catalytic (nuclease) domain which exhibits eight highly conserved acidic residues, at least one of which (Glu117) is important for phosphodiester hydrolysis but not for substrate binding [Li and Nicholson (1996) EMBO J. 15, 1421-1433]. To determine the side chain requirements for activity, Glu117 was changed to glutamine or aspartic acid. The mutant proteins were purified as (His)(6)-tagged species, and both exhibited normal homodimeric behavior as shown by chemical cross-linking. The Glu117Gln mutant is unable to cleave substrate in vitro under all tested conditions but can bind substrate. The Glu117Asp mutant also is defective in cleavage while able to bind substrate. However, low level activity is observed at extended reaction times and high enzyme concentrations, with an estimated catalytic efficiency approximately 15 000-fold lower than that of RNase III. The activity of the Glu117Asp mutant but not that of the Glu117Gln mutant can be greatly enhanced by substituting Mn(2+) for Mg(2+), with the catalytic efficiency of the Glu117Asp-Mn(2+) holoenzyme approximately 400-fold lower than that of the RNase III-Mn(2+) holoenzyme. For RNase III, a Mn(2+) concentration of 1 mM provides optimal activity, while concentrations >5 mM are inhibitory. In contrast, the Glu117Asp mutant is not inhibited by high concentrations of Mn(2+). Finally, high concentrations of Mg(2+) do not inhibit RNase III nor relieve the Mn(2+)-dependent inhibition. In summary, these experiments establish the stringent functional requirement for a precisely positioned carboxylic acid group at position 117 and reveal two classes of divalent metal ion binding sites on RNase III. One site binds either Mg(2+) or Mn(2+) and supports catalysis, while the other site is specific for Mn(2+) and confers inhibition. Glu117 is important for the function of both sites. The implications of these findings on the RNase III catalytic mechanism are discussed.
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PMID:Mechanism of action of Escherichia coli ribonuclease III. Stringent chemical requirement for the glutamic acid 117 side chain and Mn2+ rescue of the Glu117Asp mutant. 1130 28

Members of the ribonuclease III superfamily of double-stranded(ds)-RNA-specific endoribonucleases participate in diverse cellular RNA maturation and degradation pathways. A recently identified eukaryotic RNase III family member, named "Dicer", functions in the RNA interference (RNAi) pathway by producing 21--23 bp dsRNAs which target the selective destruction of homologous RNAs. RNAi is operative in animals, plants, and fungi, where it is proposed to inhibit viral reproduction and retroposon movement, as well as to participate in developmental pathways. RNAi functions in mammalian cells, including mouse oocytes and embryos. This article reports the cDNA sequence characterization and expression analysis of the mouse Dicer ortholog. On the basis of the cDNA sequence, the Dicer polypeptide is 1906 amino acids and has a predicted molecular mass of 215 kDa. Mouse Dicer contains a DExH/DEAH helicase motif; a PAZ domain; a tandem repeat of RNase III catalytic domain sequences; and a dsRNA-binding motif. The Dicer gene maps to a single locus on the distal portion of mouse Chromosome (Chr) 12. The Dicer transcript is expressed from the embryonic through adult stages of development. The Dicer transcript is also present in a wide variety of adult mouse organs. The highly conserved set of functional domains and the occurrence of a single-copy gene strongly indicate that the encoded protein is the RNase III ortholog responsible for dsRNA processing in the RNAi pathway.
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PMID:Molecular characterization of a mouse cDNA encoding Dicer, a ribonuclease III ortholog involved in RNA interference. 1188 53

The translation of non-stop mRNA (which lack in-frame stop codons) represents a significant quality control problem for all organisms. In eubacteria, the transfer-messenger RNA (tmRNA) system facilitates recycling of stalled ribosomes from non-stop mRNA in a process termed trans-translation or ribosome rescue. During rescue, the nascent chain is tagged with the tmRNA-encoded ssrA peptide, which promotes polypeptide degradation after release from the stalled ribosome. Escherichia coli possesses an additional ribosome rescue pathway mediated by the ArfA peptide. The E. coli arfA message contains a hairpin structure that is cleaved by RNase III to produce a non-stop transcript. Therefore, ArfA levels are controlled by tmRNA through ssrA-peptide tagging and proteolysis. Here, we examine whether ArfA homologues from other bacteria are also regulated by RNase III and tmRNA. We searched 431 arfA coding sequences for mRNA secondary structures and found that 82.8% of the transcripts contain predicted hairpins in their 3'-coding regions. The arfA hairpins from Haemophilus influenzae, Proteus mirabilis, Vibrio fischeri, and Pasteurella multocida are all cleaved by RNase III as predicted, whereas the hairpin from Neisseria gonorrhoeae functions as an intrinsic transcription terminator to generate non-stop mRNA. Each ArfA homologue is ssrA-tagged and degraded when expressed in wild-type E. coli cells, but accumulates in mutants lacking tmRNA. Together, these findings show that ArfA synthesis from non-stop mRNA is a conserved mechanism to regulate the alternative ribosome rescue pathway. This strategy ensures that ArfA homologues are only deployed when the tmRNA system is incapacitated or overwhelmed by stalled ribosomes.
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PMID:Proteobacterial ArfA peptides are synthesized from non-stop messenger RNAs. 2279 16

Double-stranded(ds) RNA has diverse roles in gene expression and regulation, host defense, and genome surveillance in bacterial and eukaryotic cells. A central aspect of dsRNA function is its selective recognition and cleavage by members of the ribonuclease III (RNase III) family of divalent-metal-ion-dependent phosphodiesterases. The processing of dsRNA by RNase III family members is an essential step in the maturation and decay of coding and noncoding RNAs, including miRNAs and siRNAs. RNase III, as first purified from Escherichia coli, has served as a biochemically well-characterized prototype, and other bacterial orthologs provided the first structural information. RNase III family members share a unique fold (RNase III domain) that can dimerize to form a structure that binds dsRNA and cleaves phosphodiesters on each strand, providing the characteristic 2 nt, 3'-overhang product ends. Ongoing studies are uncovering the functions of additional domains, including, inter alia, the dsRNA-binding and PAZ domains that cooperate with the RNase III domain to select target sites, regulate activity, confer processivity, and support the recognition of structurally diverse substrates. RNase III enzymes function in multicomponent assemblies that are regulated by diverse inputs, and at least one RNase III-related polypeptide can function as a noncatalytic, dsRNA-binding protein. This review summarizes the current knowledge of the mechanisms of catalysis and target site selection of RNase III family members, and also addresses less well understood aspects of these enzymes and their interactions with dsRNA.
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PMID:Ribonuclease III mechanisms of double-stranded RNA cleavage. 2412 76

The 2201-bp spacer between the chloroplast ribosomal 16S and 23S genes ofSpinacia oleracea was sequenced. It contains the genes of the tRNA(Ile) (GAU) and tRNA(Ala) (UGC) which are both interrupted by introns of respectively 728 and 816 bp. These introns belong to the class II according to the classfication of Michel and Dujon [17]. Comparison of the rDNA spacer sequence of maize, tobacco and spinach indicates that no conserved polypeptide is encoded within the introns of the two tRNA genes and that the two main insertions/deletions between the three plants are located within two loops of the class II introns secondary structure, which is therefore conserved. Based on the sequence complementarity observed between the upstream and downstream parts, of the 16S and 23S rRNA genes, RNase III-like secondary structures involved in the processing of the rRNA precursor are proposed.
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PMID:Sequence organization of the chloroplast ribosomal spacer ofSpinacia oleracea including the 3' end of the 16S rRNA and the 5' end of the 23S rRNA. 2427 63

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