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Query: EC:3.1.26.5 (RNase P)
1,348 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Single-stranded RNA viruses often have 3'-terminal tRNA-like structures that serve as substrates for the enzymes of tRNA metabolism, including the tRNA synthases and the CCA-adding enzyme. We propose that such 3'-terminal tRNA-like structures are in fact molecular fossils of the original RNA world, where they tagged genomic RNA molecules for replication and also functioned as primitive telomeres to ensure that 3'-terminal nucleotides were not lost during replication. This picture suggests that the CCA-adding activity was originally an RNA enzyme, that modern DNA telomeres with the repetitive structure CmAn are the direct descendants of the CCA terminus of tRNA, and that the precursor of the modern enzyme RNase P evolved to convert genomic into functional RNA molecules by removing this 3'-terminal tRNA-like tag. Because early RNA replicases would have been catalytic RNA molecules that used the 3'-terminal tRNA-like tag as a template for the initiation of RNA synthesis, these tRNA-like structures could have been specifically aminoacylated with an amino acid by an aberrant activity of the replicase. We show that it is mechanistically reasonable to suppose that this aminoacylation occurred by the same sequence of reactions found in protein synthesis today. The advent of such tRNA synthases would thus have provided a pathway for the evolution of modern protein synthesis.
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PMID:tRNA-like structures tag the 3' ends of genomic RNA molecules for replication: implications for the origin of protein synthesis. 347 99

Differences in the processing of dimeric tRNASer-tRNAMet precursors derived from the Schizosaccharomyces pombe sup9 wild-type and opal suppressor genes can be attributed to conformational alterations in the tRNASer anticodon/intron domain. A comparison of the patterns obtained upon transcription of the sup9+ (wild-type) and sup9-e (opal suppressor) genes in a coupled transcription/processing extract from Saccharomyces cerevisiae reveals that the latter exhibits a greatly reduced efficiency of 5'-end maturation and is susceptible to specific endonucleolytic cleavage(s) within the intron. Free energy calculations indicate that these effects coincide with a destabilization of the wild-type anticodon/intron stem and suggest that the predominant sup9-e conformer lacks secondary structure in this region. Evidence in support of this hypothesis was obtained by analyzing the processing of sup9+ and sup9-e precursors carrying the intron base substitution, G37:10, which destroys and restores, respectively, the base-pairing potential of the proposed secondary structure and comparing the strength and temperature sensitivity of sup9-e and sup9-e G37:10 suppression in vivo in S. cerevisiae. The data indicate that the anticodon/intron structure of tRNA precursors can influence the rate of RNase P cleavage in vitro and affect tRNA expression in vivo.
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PMID:A single base change in the intron of a serine tRNA affects the rate of RNase P cleavage in vitro and suppressor activity in vivo in Saccharomyces cerevisiae. 351 87

Successive rounds of mutagenesis of a Schizosaccharomyces pombe strain bearing the UGA-reading sup3 tRNASer suppressor have been carried out for two cycles of inactivation and reactivation of the suppressor. The suppressor phenotype at each stage was found to involve different combinations of three mutations, A30, A53, and A67, in the sup3-UGA gene. Single mutations A30 and A53 inactivate the suppressor as does the presence of all three mutations. A67 by itself is phenotypically neutral, but in combination with either A30 or A53 suppressor function is restored. The frequency with which these and other complementation events occur in S. pombe demonstrates a significant potential for nucleotide sequence evolution in tRNA. Differential expression of the S. pombe genes in Saccharomyces cerevisiae suggests that the two yeasts have diverged at the transcriptional and RNA processing level. Processing of the mutant tRNA precursors in S. cerevisiae reveals a hierarchy of structural domains within the tRNA that vary in their importance for RNase P cleavage.
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PMID:Functional complementation between mutations in a yeast suppressor tRNA gene reveals potential for evolution of tRNA sequences. 353 23

A requisite step in the biosynthesis of tRNA is the removal of 5' leader sequences from tRNA precursors. We have detected an RNase P activity in yeast mitochondrial extracts that can carry out this reaction on a homologous precursor tRNA. This mitochondrial RNase P was sensitive to both micrococcal nuclease and protease, demonstrating that it requires both a nucleic acid and protein for activity. The presence of RNase P activity in vitro directly correlated with the presence of a locus on yeast mitochondrial DNA previously shown by genetic and biochemical studies to be required for tRNA maturation. The product of the locus, the 9S RNA, and this newly described mitochondrial RNase P activity cofractionated, providing further evidence that the 9S RNA is the RNA component of yeast mitochondrial RNase P.
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PMID:RNase P activity in the mitochondria of Saccharomyces cerevisiae depends on both mitochondrion and nucleus-encoded components. 353 97

The properties of the Bacillus subtilis RNase P are characterized with regard to the types and concentrations of monovalent and divalent ions required to potentiate precursor tRNA cleavage by the protein-RNA holoenzyme and the catalytic RNA alone. The ionic dependence of the RNase P RNA-catalyzed reaction in part seems due to a requirement for ion shielding between substrate and catalytic RNAs. The RNase P protein, which binds to RNA nonspecifically and tightly, likely serves, in part, as a cation screen. However, the character of the ion dependence of the RNA catalysis, the inhibition by high SO2-4 concentration, and potentiation by solvents suggest that RNA conformational transition may be involved in the reaction. It is proposed that the reason for catalysis by RNA in the RNase P reaction may be a requirement for fluidity in the structure of the catalyst, so that it can accommodate many tRNA substrates, which vary in their structural details.
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PMID:Ion dependence of the Bacillus subtilis RNase P reaction. 392 45

Certain nucleotides in precursor RNA of tRNA(Tyr) of Escherichia coli were modified in vitro with a preparation of partially purified E. coli enzyme containing ribothymidine- and pseudouridine-forming activity. The only nucleotides modified in vitro are the same as those found modified in mature tRNA. The best substrate for these modifying enzymes is the RNase P cleavage product of the precursor RNA, which contains the mature tRNA sequence. Of the two pseudouridines found in mature tRNA, one (in the TPsiC sequence) can be formed in intact precursor RNA. The other (in the anticodon stem) can only be formed in the cleaved precursor RNA. The presence of modified nucleotides in the precursor RNA does not enhance its rate of cleavage by RNase P.
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PMID:Nucleotide modification in vitro of the precursor of transfer RNA of Escherichia coli. 458 57

The structure of M1 RNA, the RNA component of Escherichia coli RNase P, has been probed by mild digestion with a variety of ribonucleases. The results have been used to generate a model for the two-dimensional structure of M1 RNA. This model is similar in many respects to an earlier model that was based entirely on theoretical considerations. M1 RNA was digested with RNase T1 in buffer containing 10 mM MgCl2 (in which M1 RNA, by itself, has no catalytic activity) and in buffer containing 60 mM MgCl2 (in which M1 RNA can cleave precursors to tRNA molecules). Under these conditions, the main features of the secondary structure are similar, but several minor differences are apparent. Such subtle changes in structure are also observed when M1 RNA is present in a binary complex with a substrate molecule, the precursor to E. coli tRNATyr.
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PMID:Structure in solution of M1 RNA, the catalytic subunit of ribonuclease P from Escherichia coli. 608 7

Ribonuclease P from Bacillus subtilis cleaves a Gln-Leu tRNA dimeric precursor from bacteriophage T4-infected Escherichia coli, yielding products identical with those generated by the E. coli RNase P. Using this tRNA dimer as an assay substrate, the RNase of P of B. subtilis was shown to consist of at least two components, one of which bands in CsCl equilibrium buoyant density centrifugation at 1.7 g/ml, characteristic of a protein x nucleic acid complex. Both this component and a second, retrieved from the low density (less than 1.4 g/ml) regions of CsCl gradients, are required for RNase P activity. Enzyme activity is abolished by treating the component of density 1.7 g/ml with insoluble RNase A prior to assay. These observations suggest that the RNase P of B. subtilis, like that of E. coli, contain a RNA component essential for activity. That this RNA component is of functional importance, and not an artifact of isolation procedures, is supported by the fact that it is observed in these two phylogenetically disparate organisms.
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PMID:RNase P of Bacillus subtilis has a RNA component. 615 38

RNAase P (EC 3.1.26.5) activity has been identified in chick embryo thigh tissue on the basis of specific cleavage of Escherichia coli 129 nucleotide tRNATyr precursor and has been partially purified by the procedure used for human tissue culture KB cell RNAase P. RNAase P from chick resembles the KB cell RNAase P in substrate specificity, requirement for a divalent cation (Mg2+) and a monovalent cation (K+, Na+ or NH4+) for activity, inhibition by bulk tRNA, ready inactivation by proteases, and increasing instability; with purification. RNAase P activity is also present in whole chick embryos, as well as in liver and heart tissues. Furthermore, crude preparations of RNAase P from chick embryo heart tissue are relatively free of contaminating nucleases.
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PMID:Identification of ribonuclease P activity from chick embryos. 616 Aug 76

The purified protein moiety of ribonuclease P (EC 3.1.26.5) from Escherichia coli, a single polypeptide of molecular weight approximately 17 500, has not catalytic activity by itself on several RNA substrates. However, when it is marked in vitro with an RNA species called M1 RNA, RNase P activity is reconstituted. The rate at which the purified RNase P cleaves any particular tRNA precursor molecule depends on the identity of that tRNA precursor.
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PMID:Properties of purified ribonuclease P from Escherichia coli. 616 92

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