EC:3.1.26.5 - FACTA Search

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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

Ribonuclease P RNA is the catalytic moiety of the ribonucleoprotein enzyme that endonucleolytically cleaves precursor sequences from the 5' ends of pre-tRNAs. The bacterial RNase P RNA-tRNA complex was examined with a footprinting approach, utilizing chemical modification to determine RNase P RNA nucleotides that potentially contact tRNA. RNase P RNA was modified with dimethylsulfate or kethoxal in the presence or absence of tRNA, and sites of modification were detected by primer extension. Comparison of the results reveals RNase P bases that are protected from modification upon binding tRNA. Analyses were carried out with RNase P RNAs from three different bacteria: Escherichia coli, Chromatium vinosum and Bacillus subtilis. Discrete bases of these RNAs that lie within conserved, homologous portions of the secondary structures are similarly protected. One protection among all three RNAs was attributed to the precursor segment of pre-tRNA. Experiments using pre-tRNAs containing precursor segments of variable length demonstrate that a precursor segment of only 2-4 nucleotides is sufficient to confer this protection. Deletion of the 3'-terminal CCA sequence of tRNA correlates with loss of protection of a particular loop in the RNase P RNA secondary structure. Analysis of mutant tRNAs containing sequential 3'-terminal deletions suggests a relative orientation of the bound tRNA CCA to that loop.
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PMID:Phylogenetic comparative chemical footprint analysis of the interaction between ribonuclease P RNA and tRNA. 752 Dec 96

Ribonuclease P, which contains a catalytic RNA subunit, cleaves 5' precursor-specific sequences from pre-tRNAs. It was previously shown that the RNase P RNA optimally cleaves substrates which contain the mature, 3'-terminal CCA of tRNA. In order to determine the contributions of those individual 3'-terminal nucleotides to the interaction, pre-tRNAs that have CCA, only CC or C or are without CCA at the 3'-end were synthesized by run-off transcription, tested as substrates for cleavage by RNase P RNA and used in photoaffinity crosslinking experiments to examine contact sites in the ribozyme. In order to generalize the results, analyses were carried out using three different bacterial RNase P RNAs, from Escherichia coli, Bacillus subtilis and Thermotoga maritima. At optimal (Kcat/Km) ionic strength (1 M NH4+/25 mM Mg2+), Km increases incrementally 3- to 10-fold upon stepwise removal of each nucleotide from the 3'-end. At high ionic strength (2 M NH4+/50 mM Mg2+), which suppresses conformational effects, removal of the 3'-terminal A had little effect on Km, indicating that it is not a specific contact. Analysis of the deletion and substitution mutants indicated that the C residues act specially; their contribution to binding energy at high ionic strength (approximately 1 kcal/mol) is consistent with a non-Watson-Crick interaction, possibly irregular triple-strand formation with some component of the RNase P RNA. In agreement with previous studies, we find that the RNase P holoenzyme in vitro does not discriminate between tRNAs containing or lacking CCA. The structural elements of the three RNase P RNAs in proximity to the 3'-end of tRNA were examined by photoaffinity crosslinking. Photoagent-labeled tRNAs with 3'-terminal CCA, only CC or C, or lacking all these nucleotides were covalently conjugated to the three RNase P RNAs by irradiation and the sites of crosslinks were mapped by primer extension. The main crosslink sites are located in a highly conserved loop (probably an irregular helix) that is part of the core of the RNase P RNA secondary structure. The crosslinking results orient the CCA of tRNA with respect to that region of the RNase P RNA.
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PMID:Interaction of the 3'-end of tRNA with ribonuclease P RNA. 752 35

Base pairing between the substrate and the ribozyme has previously been shown to be essential for catalytic activity of most ribozymes, but not for RNase P RNA. By using compensatory mutations we have demonstrated the importance of Watson-Crick complementarity between two well-conserved residues in Escherichia coli RNase P RNA (M1 RNA), G292 and G293, and two residues in the substrate, +74C and +75C (the first and second C residues in CCA). We suggest that these nucleotides base pair (G292/+75C and G293/+74C) in the ribozyme-substrate complex and as a consequence the amino acid acceptor stem of the precursor is partly unfolded. Thus, a function of M1 RNA is to anchor the substrate through this base pairing, thereby exposing the cleavage site such that cleavage is accomplished at the correct position. Our data also suggest possible base pairing between U294 in M1 RNA and the discriminator base at position +73 of the precursor. Our findings are also discussed in terms of evolution.
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PMID:Base pairing between Escherichia coli RNase P RNA and its substrate. 752 71

We have studied the interaction of 3'-end variants of a (pre-)tRNAGly with ribonuclease P (RNase P) RNAs from Escherichia coli and Thermus thermophilus. To dissect the thermodynamics of tRNA binding from the overall catalytic reaction, specific binding of mature tRNAGly variants to RNase P RNAs was studied by gel retardation. A newly developed assay, based on the reduction of Pb(2+)-hydrolysis at the CCA end due to complex formation of tRNA and RNase P RNA, was utilized to confirm the dissociation constants. The binding data were supplemented by single and multiple turnover kinetic analyses of the corresponding pre-tRNAGly variants. For E. coli RNase P RNA the following results were obtained. Extensions of CCA by pCp or three nucleotides (AUA) stabilized gel-resolved tRNAGly binding by 1 to 1.5 kcal/mol. Changing the first C in CCA to A, G or U resulted in a more than 100-fold reduction in binding affinity, which corresponds to a loss of 3.5 to 4.5 kcal/mol of binding energy. However, single turnover rate constants were only slightly affected, indicating that a disruption or loss of the tRNA 3'-end-mediated interaction with RNase P RNA does not preferentially destabilize the transition state. Our data suggest another kinetic step following initial substrate binding to E. coli RNase P RNA (possibly a conformational rearrangement). For T. thermophilus RNase P RNA, product release of wild-type tRNAGly CCAAUA was not rate-limiting in the multiple turnover reaction. However, the effects of CCA mutations were similar to those attained with E. coli RNase P RNA. This supports the notion that a high-affinity binding site for the tRNA 3'-end is a ubiquitous feature of eubacterial P RNAs. Finally, the results obtained here provide further evidence that the gel retardation assay is suitable for binding interference studies to identify the structural elements of RNase P RNAs and tRNAs that are crucial for the formation of a specific RNase P RNA-tRNA complex.
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PMID:Kinetics and thermodynamics of the RNase P RNA cleavage reaction: analysis of tRNA 3'-end variants. 753 57

The C4 repressor of the temperate bacteriophages P1 and P7 inhibits antirepressor (Ant) synthesis and is essential for establishment and maintenance of lysogeny. C4 is an antisense RNA acting on a target, Ant mRNA, which is transcribed from the same promoter. The antisense-target RNA interaction requires processing of C4 RNA from a precursor RNA. Here we show that 5' maturation of C4 RNA in vivo depends on RNase P. In vitro, Escherichia coli RNase P and its catalytic RNA subunit (M1 RNA) can generate the mature 5' end of C4 RNA from P1 by a single endonucleolytic cut, whereas RNase P from the E. coli rnpA49 mutant, carrying a missense mutation in the RNase P protein subunit, is defective in the 5' maturation of C4 RNA. Primer extension analysis of RNA transcribed in vivo from a plasmid carrying the P1 c4 gene revealed that 5'-mature C4 RNA was the predominant species in rnpA+ bacteria, whereas virtually no mature C4 RNA was found in the temperature-sensitive rnpA49 strain at the restrictive temperature. Instead, C4 RNA molecules carrying up to five extra nucleotides beyond the 5' end accumulated. The same phenotype was observed in rnpA+ bacteria which harbored a plasmid carrying a P7 c4 mutant gene with a single C-->G base substitution in the structural homologue to the CCA 3' end of tRNAs. Implications of C4 RNA processing for the lysis/lysogeny decision process of bacteriophages P1 and P7 are discussed.
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PMID:Precursor of C4 antisense RNA of bacteriophages P1 and P7 is a substrate for RNase P of Escherichia coli. 759 35

A gel-shift assay was devised to detect stable enzyme-substrate (E-S) complexes between M1 RNA, the catalytic subunit of RNase P from Escherichia coli, and its tRNA precursor substrates. The use of deletion derivatives of M1 RNA in the gel-shift assay has allowed us to identify regions of the enzyme that are involved in the binding of the substrate or that are necessary for catalytic activity. Fragments of substrates that contain the 3' CCA sequence bind preferentially to regions in the 5' half of M1 RNA, while 5' leader sequences interact primarily with regions in the 3' half of M1 RNA. The 5' leader sequence present in the precursor to tRNA(Tyr)su3 from E. coli plays an important role in the formation of stable E-S complexes with M1 RNA. The CCA sequence at the 3' end of precursor tRNA substrates is involved in the product-release step of the reaction that is catalyzed by M1 RNA. Direct measurements of the concentrations of all the components in the reaction catalyzed by M1 RNA facilitated a new approach to the kinetic analysis of the action of the enzyme.
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PMID:A physical assay for and kinetic analysis of the interactions between M1 RNA and tRNA precursor substrates. 768 47

Truncated precursor tRNAs lacking the D arm or anticodon arm were studied in vitro as substrates for RNase P enzymes from Escherichia coli, Thermus thermophilus (eubacteria), and HeLa. Deletion of the D arm still allowed 5'-processing by E. coli RNase P, but strongly impaired maturation by T. thermophilus and HeLa extracts. In contrast, deletion of the anticodon arm had no influence on processing by RNase P activities from all three organisms. Inhibition kinetics and gel retardation studies showed that deletion of the D arm leads to low-affinity binding to E. coli RNase P RNA (M1 RNA). However, the E. coli enzyme appears to form sufficiently strong contacts in the region of the T arm, acceptor stem, and CCA terminus to still allow productive enzyme-substrate interaction even in the absence of the structural contribution provided by the D arm. Pb(2+)-induced hydrolysis of a tRNAGly from T. thermophilus gave identical cleavage patterns in the D arm and anticodon loop in the absence and presence of E. coli M1 RNA, whereas lead hydrolysis was strongly reduced at the CUCCAA 3'-terminus due to the presence of the enzyme.
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PMID:Role of the D arm and the anticodon arm in tRNA recognition by eubacterial and eukaryotic RNase P enzymes. 769 52

tRNA processing is a central event in mammalian mitochondrial gene expression. We have identified key enzymatic activities (ribonuclease P, precursor tRNA 3'-endonuclease, and ATP(CTP)-tRNA-specific nucleotidyltransferase) that are involved in HeLa cell mitochondrial tRNA maturation. Different mitochondrial tRNA precursors are cleaved precisely at the tRNA 5'- and 3'-ends in a homologous mitochondrial in vitro processing system. The cleavage at the 5'-end precedes that at the 3'-end, and the tRNAs are substrates for the specific CCA addition in the same in vitro system. Using a comparative enzymatic approach as well as biochemical and immunological techniques, we furthermore demonstrate that human cells contain two distinct enzymes that remove 5'-extensions from tRNA precursors, the previously characterized nuclear and the newly identified mitochondrial ribonuclease P. These two cellular isoenzymes have different substrate specificities that seem to be well adapted to their structurally disparate mitochondrial and nuclear tRNA substrates. This kind of approach may also help to understand the structural diversities and commonalities of tRNAs.
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PMID:Human mitochondrial tRNA processing. 775 47

RNase P is responsible for the maturation of the 5'-termini of tRNA molecules in all cells studied to date. This ribonucleoprotein has to recognize and identify its cleavage site on a large number of different precursors. This review covers what is currently known about the function of the catalytic subunit of Escherichia coli RNase P, M1 RNA, and the protein subunit, C5, in particular with respect to cleavage-site selection. Recent genetic and biochemical data show that the two C residues in the 3'-terminal CCA sequence of a precursor interact with the enzyme through Watson-Crick base-pairing. This is suggested to result in unfolding of the amino acid acceptor-stem and exposure of the cleavage site. Furthermore, other close contact points between M1 RNA and its substrate have recently been identified. These data, together with the two existing three-dimensional structure models of M1 RNA in complex with its substrate, establish a platform that will enable us to seek an understanding of the underlying mechanism of cleavage by this elusive enzyme.
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PMID:RNase P--a 'Scarlet Pimpernel'. 751 85

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