Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.27.5 (RNase)
 17,967 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The tRNATyr precursor molecule, synthesized from phi 80 psu3+ DNA (containing a single tRNA gene) by DNA-dependent RNA polymerase and q factor, was about 205 nucleotides long. The main product of its digestion with a ribonuclease tii preparation from Escherichia coli showed the same electrophoretic mobility as tRNAtyr precursor isolated in vivo and was found to be identical to it when analysed using fingerprint techniques. This intermediate precursor synthesized in vitro was converted further by processing with ribonuclease P into an RNA identical size to mature tRNATyr. It was concluded that the initiation of transcription of the tRNATyr gene in vitro occurs at the same site as that of transcription in vivo and a termination occurs at about 80 nucleotides beyond the CCA end of tRNATyr.
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PMID:Processing by ribonuclease II of the tRNATyr precursor of Escherichia coli synthesized in vitro. 32 7

The pyrE gene, encoding the pyrimidine biosynthetic enzyme orotate phosphoribosyltransferase, is the promoter distal gene of the dicistronic orfE-pyrE operon. The promoter proximal orfE gene, whose transcription and translation is important for regulation of the pyrE attenuator, encodes a 238-amino acid residue protein which was recently identified as the phosphorolytic ribonuclease, RNase PH, that removes nucleotides from the 3' ends of tRNA precursors. In this paper we report the construction of a plasmid, which overexpresses the orfE and pyrE gene products substantially, as well as the purification of the OrfE protein by ammonium sulfate precipitation and chromatography on phosphocellulose. The highly purified protein catalyzes the phosphorolytic cleavage of poly(A) at a rate of 1.6 mumol/min/mg and the formation of CDP from tRNA-CCA-Cn and orthophosphate at a rate equal to 0.14 mumol/min/mg, as characteristic for RNase PH. OrfE/RNase PH contains helix-turn-helix motifs resembling those in DNA-binding proteins, and it binds nonspecifically to DNA. On SDS gels, OrfE/RNase PH migrates as two distinct protein bands. This heterogeneity might be caused by post-translational modification other than proteolysis, or may be an electrophoretic artifact. The native protein is composed of two or more subunits.
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PMID:Overexpression and rapid purification of the orfE/rph gene product, RNase PH of Escherichia coli. 151 52

RNase PH is a Pi-dependent exoribonuclease that can act at the 3' terminus of tRNA precursors in vitro. To obtain information about the function of this enzyme in vivo, the Escherichia coli rph gene encoding RNase PH was interrupted with either a kanamycin resistance or a chloramphenicol resistance cassette and transferred to the chromosome of a variety of RNase-resistant strains. Inactivation of the chromosomal copy of rph eliminated RNase PH activity from extracts and also slowed the growth of many of the strains, particularly ones that already were deficient in RNase T or polynucleotide phosphorylase. Introduction of the rph mutation into a strain already lacking RNases I, II, D, BN, and T resulted in inviability. The rph mutation also had dramatic effects on tRNA metabolism. Using an in vivo suppressor assay we found that elimination of RNase PH greatly decreased the level of su3+ activity in cells deficient in certain of the other RNases. Moreover, in an in vitro tRNA processing system the defect caused by elimination of RNase PH was shown to be the accumulation of a precursor that contained 4-6 additional 3' nucleotides following the -CCA sequence. These data indicate that RNase PH can be an essential enzyme for the processing of tRNA precursors.
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PMID:RNase PH is essential for tRNA processing and viability in RNase-deficient Escherichia coli cells. 164 89

Modification of B. subtilis EF-Tu by N-tosyl-L-phenylalanyl chloromethane destroyed its ability to promote protein synthesis and resulted in selective dissociation of the two binding activities of the protein for aminoacyl-tRNA. The modified EF-Tu was completely ineffective in the protection of the 3'-terminal CCA structure of tRNA against pancreatic ribonuclease, while remaining almost fully active in the protection of the ester bond between the 3'-terminal adenosine and the amino acid residue in aminoacyl-tRNA.
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PMID:Modification of Bacillus subtilis elongation factor Tu by N-tosyl-L-phenylalanyl chloromethane abolishes its ability to interact with the 3'-terminal polynucleotide structure but not with the acyl bond in aminoacyl-tRNA. 250 33

The accessibility of nucleotides in Escherichia coli tRNAfMet to chemical and enzymatic probes in the presence and absence of methionyl-tRNA synthetase has been investigated. Dimethyl sulfate was used to probe the reactivity of cytosine and guanosine residues. The N-3 position of the wobble anticodon base, C34, was strongly protected from methylation in the tRNA-synthetase complex. A synthetase-induced conformational change in the anticodon loop was suggested by the enhanced reactivity of C32 in the presence of enzyme. Cytosine residues in the dihydrouridine loop and in the 3'-terminal CCA sequence showed little or no change in reactivity. Methylation of the N-7 position of guanosine residues G42, G52, and G70 was partially inhibited by the synthetase. Nuclease digestion of tRNAfMet with alpha-sarcin in the presence of 1-2 mM Mg2+ resulted in cleavage mainly at C71 in the acceptor stem and was strongly inhibited by synthetase. Other nuclease digestion experiments using the single strand specific nucleases RNase A and RNase T1 revealed weak protection of nucleotides in the D loop and strong protection of nucleotides in the anticodon on complex formation. The present data, together with previous structure-function studies on this system, indicate strong binding of methionyl-tRNA synthetase to the anticodon of tRNAfMet, leading to a change in the conformation of the anticodon loop and stem. We propose that this, in turn, produces more distant, and possibly relatively subtle, conformational changes in other parts of the tRNA structure that ultimately lead to proper orientation of the 3' terminus of the tRNA with respect to the active site of the enzyme.
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PMID:Study of the interaction of Escherichia coli methionyl-tRNA synthetase with tRNAfMet using chemical and enzymatic probes. 309 57

Rat liver mitochondria isolated in sucrose-N-tris(hydroxymethyl)methyl-2-aminoethane-sulphonic acid (TES) incorporated [(3)H]UTP into RNA for 1h. Incorporation was inhibited 50% by 1mug of actinomycin D/ml, 1mug of acriflavine/ml and 0.5mug of ethidium bromide/ml but was insensitive to rifampicin, rifamycin SV, streptovarcin and deoxyribonuclease. After the first 10min of incubation, the synthesis was insensitive to ribonuclease. RNA synthesis by mitochondria isolated in sucrose-EDTA was insensitive to actinomycin D and sensitive to ribonuclease during the first 10min of the incubation but thereafter the sensitivities were the same as for mitochondria isolated in sucrose-TES. In a hypo-osmotic medium the relative extent of incorporation of the four ribonucleoside triphosphates into RNA was CTP>UTP=ATP>>GTP. In an iso-osmotic medium the incorporation of CTP and GTP decreased. All four nucleotides were incorporated into RNA in a DNA-dependent process, as indicated by the inhibition by actinomycin D. In addition, CTP and ATP were incorporated into the CCA end of mitochondrial tRNA. ATP was also incorporated into an unidentified acid-insoluble compound, which hydrolysed in alkali to a product that was not ATP, ADP or 5'- or 2(3')-AMP. Atractyloside inhibited the incorporation of ATP into RNA with 50% inhibition at 2-3nmol/mg of protein. The [(3)H]UTP-labelled RNA had peaks of 16S and 13S characteristic of mitochondrial rRNA. In addition a peak at 20-21S was observed as well as heterogeneous RNA sedimenting throughout the gradient. The synthesis of all these species was inhibited by actinomycin D, indicating that rat liver mitochondrial DNA codes for mitochondrial rRNA as well as other as yet unidentified species.
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PMID:Synthesis of ribonucleic acid by isolated rat liver mitochondria. 440 94

A temperature-sensitive (t.s.) tRNATrp from Escherichia coli has a single base change from the wild type (w.t.) species, which results in the loss of a base pair at the bottom of the CCA stem of the cloverleaf structure. Thermodynamic studies on this t.s. tRNA show that it is more susceptible to denaturation than the w.t. due to a larger change in the entropy of denaturation. Correlated with this thermodynamic result is the finding that the denatured t.s. tRNA's T psi C loop is more susceptible to digestion by T1 RNase, suggesting that it has greater freedom than the corresponding structure on the denatured w.t. molecule. In contrast, the native form of the t.s. tRNATrp is very similar to the w.t. with regard to aminoacylation, T1 RNase susceptibility, and column chromatographic mobility, despite the fact that it necessarily has one less base pair. In addition, the well known denaturation-dependent shift in column chromatographic mobility, which is observed for both the t.s. and w.t. molecules, depends on a modification in the anticodon loop, since tRNATrp lacking that modification does not shift when denatured. Thus, though it is not usually thought to be implicated, denaturation probably affects the conformation of the anticodon loop. The lethal phenotype of the mutant at high temperature, defective attenuation of the tryptophan biosynthetic operon in the mutant, and some aspects of the denatured state are clarified by these findings.
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PMID:The structure and aminoacylation of a temperature-sensitive tRNATrp (Escherichia coli). 676 36

The RNA isolated from RNase-treated proteasome preparations from human erythrocytes, HeLa cells, the archaeon Thermoplasma acidophilum and also from recombinant proteasomes of T. acidophilum expressed in Escherichia coli was characterized. The RNA associated with structurally similar protein particles, namely with the two molecular chaperones, groEL from E. coli and with the thermosome from T. acidophilum, served as controls. Electrophoretic analysis on polyacrylamide gels of the radioactively end-labelled RNA revealed a very similar size distribution pattern, irrespectively of the protein particles from which they had been isolated. The predominant RNA species were in the size ranges 80 nucleotides and 120 nucleotides, respectively. Partial sequencing of their terminal regions by mobility-shift analysis revealed that, of the proteasomes from human erythrocytes, the approximately 80-nucleotide-long RNA consists of a heterogenous population of mostly tRNA species because they carried the tRNA-specific 3'-terminal sequence motif 5'-CCA-3'. The RNA in the size range 120 nucleotides isolated from the proteasomes of human erythrocytes and of T. acidophilum was also heterogeneous and displayed, in the terminal regions, a remarkable sequence similarity to the corresponding regions of the 5S rRNA from the same and different organisms. The total content of RNA of all the protein particles was quantified and found to be consistently sub-stoichiometric. All these findings strongly suggest that RNA associated with the proteasomes and with the molecular chaperones originate from the abundant cellular pool of the tRNAs and 5S rRNAs which bind non-specifically to these large protein particles.
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PMID:Proteasome-associated RNAs are non-specific. 752 80

The prr locus was originally described as coding a ribonuclease that is activated after phage T4 infection to cut within the anticodon of a specific tRNA, inactivating protein synthesis and thus blocking phage development. Wild-type T4 phage has two genes coding the enzymes polynucleotide kinase and RNA ligase, whose only function seems to be to repair the damage done by the anticodon nuclease. As the only apparent function of the prr ribonuclease is to combat phage infection, it can be considered as an RNA-based restriction enzyme. In non-infected cells, the prr enzyme is kept inactive in a complex with three other proteins which were predicted on the basis of DNA homologies to be the subunits of a type IC DNA restriction and modification system. Unlike other type IC systems so far characterized, prr is chromosomally rather than plasmid coded. However, sequences upstream from prr also have homology with sequences from the plasmid R124 and the prophage P1. We have now investigated the prr system and shown that it is indeed a bona fide type IC system which we call EcoprrI, and which is active both in vivo and in vitro. The system is fully functional even in the absence of the anticodon nuclease and seems to be a typical type I enzyme. EcoprrI recognizes the sequence CCA(N7)RTGC. One peculiarity is that, with low efficiency, EcoprrI will recognize and methylate variants of its recognition sequence such as CCT(N7)ATGC, which is methylated in one strand of the DNA only.
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PMID:The Escherichia coli prr region encodes a functional type IC DNA restriction system closely integrated with an anticodon nuclease gene. 814 41

Inhibition and substrate competition kinetics demonstrated that tRNA is a highly preferred substrate of thyroid alkaline RNase. The pyrimidine-specific RNase cleaved poly(C) 2.8 x 10(5) faster than poly(U). kcat:K(M) ratios for tRNA and poly(C) based on molecular weights failed to predict preference when both were present. Competition experiments between poly(C) and tRNA revealed tRNA was a tight-binding competing substrate and the cytidylate residues in the 3'-CCA terminus to tRNA were preferred about 280:1 over those in poly(C). Poly(U) was competitive with tRNA. When poly(C) was the substrate, inhibition type by poly(G) depended on poly(G) concentration. Neither tRNA lacking its 3' terminal cytidylyl(3'-5')adenosine and terminating in a 2':3' cCMP residue, tRNA lacking its 3' terminal 5'AMP residue, guanosine, nor guanylyl(3'-5')guanylyl(3'-5')guanosine were inhibitors. Product inhibition by adenosine and 2':3' cCMP showed the kinetic mechanism for cleavage of tRNA was ordered uni bi.
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PMID:Inhibition and substrate competition kinetics in analysis of porcine thyroid alkaline ribonuclease's specificity toward synthetic RNA's and tRNA. 931 16


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