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)

PCR amplification of template DNAs extracted from mixed, naturally occurring microbial populations, using oligonucleotide primers complementary to highly conserved sequences, was used to obtain a large collection of diverse RNase P RNA-encoding genes. An alignment of these sequences was used in a comparative analysis of RNase P RNA secondary and tertiary structure. The new sequences confirm the secondary structure model based on sequences from cultivated organisms (with minor alterations in helices P12 and P18), providing additional support for nearly every base pair. Analysis of sequence covariation using the entire RNase P RNA data set reveals elements of tertiary structure in the RNA; the third nucleotides (underlined) of the GNRA tetraloops L14 and L18 are seen to interact with adjacent Watson-Crick base pairs in helix P8, forming A:G/C or G:A/U base triples. These experiments demonstrate one way in which the enormous diversity of natural microbial populations can be used to elucidate molecular structure through comparative analysis.
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PMID:Comparative analysis of ribonuclease P RNA using gene sequences from natural microbial populations reveals tertiary structural elements. 861 Jan 58

We have studied variants of Escherichia coli RNase P RNA with base exchanges in the joining regions flanking helix P18, which form part of the ribozyme core structure. Mutant RNase P RNAs were analyzed for: (1) specific tRNA binding by gel retardation; (2) catalytic performance in single turnover reactions; (3) structural perturbations utilizing Pb2+ -induced hydrolysis; and (4) in vivo function by complementation analysis in E. coli RNase P mutant strains. Our in vitro experiments revealed that the base moieties of nucleotides (nt) 303 and 331 to 333 neither significantly contribute to tRNA binding or structural stabilization of RNase P RNA nor to active site chemistry. Single base exchanges at nt 300, 301, and 330 reduced tRNA binding, while having little effect on the catalytic rate, which demonstrates that these nucleotides are involved in forming the high affinity (pre-)tRNA binding site. In contrast, point mutations at the strictly conserved positions nt 328, 329, 334 and 335 reduced tRNA binding affinity as well as the catalytic rate, suggesting that these mutations additionally disrupted important interactions in the catalytic center. Probing by Pb2+ revealed that particularly the mutations that affected catalytic function most strongly perturbed a more extended region (nt 248 to 335) known to be involved in tRNA binding. Under high salt conditions (> or = 0.8 M NH4+), catalytic defects of the mutant RNase P RNAs were much less pronounced, suggesting that structural perturbations leading to increased electrostatic repulsion between phosphate groups were the main cause for observed functional defects. Only mutant C334 retained a largely increased pre-steady-state K(m(pss)) under high salt conditions. We conclude that the base at position 334 is directly involved in a contact crucial to pre-tRNA binding. A complementation analysis demonstrated the important role in vivo of the joining regions flanking helix P18. None of the bases could be mutated without affecting bacterial viability.
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PMID:Mutational analysis of the joining regions flanking helix P18 in E. coli RNase P RNA. 867 78

The protein subunit of Escherichia coli ribonuclease P (which has a cysteine residue at position 113) and its single cysteine-substituted mutant derivatives (S16C/C113S, K54C/C113S and K66C/C113S) have been modified using a sulfhydryl-specific iron complex of EDTA-2- aminoethyl 2-pyridyl disulfide (EPD-Fe). This reaction converts C5 protein, or its single cysteine-substituted mutant derivatives, into chemical nucleases which are capable of cleaving the cognate RNA ligand, M1 RNA, the catalytic RNA subunit of E. coli RNase P, in the presence of ascorbate and hydrogen peroxide. Cleavages in M1 RNA are expected to occur at positions proximal to the site of contact between the modified residue (in C5 protein) and the ribose units in M1 RNA. When EPD-Fe was used to modify residue Cys16 in C5 protein, hydroxyl radical-mediated cleavages occurred predominantly in the P3 helix of M1 RNA present in the reconstituted holoenzyme. C5 Cys54-EDTA-Fe produced cleavages on the 5' strand of the P4 pseudoknot of M1 RNA, while the cleavages promoted by C5 Cys66-EDTA-Fe were in the loop connecting helices P18 and P2 (J18/2) and the loop (J2/4) preceding the 3' strand of the P4 pseudoknot. However, hydroxyl radical-mediated cleavages in M1 RNA were not evident with Cys113-EDTA-Fe, perhaps indicative of Cys113 being distal from the RNA-protein interface in the RNase P holoenzyme. Our directed hydroxyl radical-mediated footprinting experiments indicate that conserved residues in the RNA and protein subunit of the RNase-P holoenzyme are adjacent to each other and provide structural information essential for understanding the assembly of RNase P.
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PMID:Mapping RNA-protein interactions in ribonuclease P from Escherichia coli using disulfide-linked EDTA-Fe. 1065 15

RNase P RNA gene (rnpB) sequences were PCR-amplified from different members of the Prochlorococcus group. Aligned nucleotide sequences revealed a variance of up to 27% for rnpB. Comparative secondary structure analysis showed that domains P12, P18 and P19 of these novel ribozyme sequences in particular are highly divergent. Thus, these regions in RNase P RNA might serve as potential targets for deoxyoligonucleotide primers for the identification of specific genotypes of Prochlorococcus and for probing field populations. Phylogenetic trees constructed from RNase P RNA sequences were similar to, but not fully congruent with, those derived previously using sequences of the 16S rRNA gene. However, the application of rnpB sequences allowed a better resolution within clades of very closely related genotypes. As is known from 16S rRNA-based phylogenetic trees, sequences from individual strains clustered according to their physiology and the conditions at the original site of isolation, rather than their geographical origin. All sequences obtained from high-light-adapted strains formed a single coherent clade, as did the four sequences from low-light-adapted strains that were previously isolated from the North Atlantic and the subtropical North Pacific. This suggests a remarkable genetic stability of Prochlorococcus genotypes that thrive under identical ecological conditions.
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PMID:Conserved and variable domains within divergent rnase P RNA gene sequences of Prochlorococcus strains. 1214 54

The RNA subunit of mitochondrial RNase P (mtP-RNA) is encoded by a mitochondrial gene (rnpB) in several ascomycete fungi and in the protists Reclinomonas americana and Nephroselmis olivacea. By searching for universally conserved structural elements, we have identified previously unknown rnpB genes in the mitochondrial DNAs (mtDNAs) of two fission yeasts, Schizosaccharomyces pombe and Schizosaccharomyces octosporus; in the budding yeast Pichia canadensis; and in the archiascomycete Taphrina deformans. The expression of mtP-RNAs of the predicted size was experimentally confirmed in the two fission yeasts, and their precise 5' and 3' ends were determined by sequencing of cDNAs generated from circularized mtP-RNAs. Comparative RNA secondary structure modeling shows that in contrast to mtP-RNAs of the two protists R. americana and N. olivacea, those of ascomycete fungi all have highly reduced secondary structures. In certain budding yeasts, such as Saccharomycopsis fibuligera, we find only the two most conserved pairings, P1 and P4. A P18 pairing is conserved in Saccharomyces cerevisiae and its close relatives, whereas nearly half of the minimum bacterial consensus structure is retained in the RNAs of fission yeasts, Aspergillus nidulans and Taphrina deformans. The evolutionary implications of the reduction of mtP-RNA structures in ascomycetes will be discussed.
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PMID:Mitochondrial RNase P RNAs in ascomycete fungi: lineage-specific variations in RNA secondary structure. 1292 56

RNase P is a ribonucleoprotein that cleaves tRNA precursors at their 5'-end. Mitochondrion-encoded RNA subunits of mitochondrial RNase P (mtP-RNA) have been identified in jakobid flagellates such as Reclinomonas americana, in the prasinophyte alga Nephroselmis olivacea, and in several ascomycete and zygomycete fungi. While the structures of ascomycete mtP-RNAs are highly reduced, those of jakobids, prasinophytes, and zygomycetes retain most conserved features of their bacterial counterparts. Therefore, these mtP-RNAs might be active in vitro in the absence of a protein subunit, as are bacterial P-RNAs. Here we present a comparative structural analysis including seven newly characterized jakobid mtP-RNAs. We investigate ribozyme activities of mtP-RNAs and find that even the most bacteria-like molecules of jakobids are inactive in vitro. However, when certain domains of jakobid and N. olivacea mtP-RNAs are replaced with those from Escherichia coli, these hybrid RNAs show catalytic activity. In vitro mutagenesis of these hybrid mtP-RNAs shows that various structural elements play a critical role in ribozyme catalysis and provide further support for the presence of these elements in mtP-RNAs. These include GNRA tetraloops in helix P14 and P18 of Jakoba libera, and a remnant P3 pairing in Seculamonas ecuadoriensis. Finally, we will discuss reasons for the failure of mtP-RNAs to show catalytic activity in the absence of P-proteins based on our mutagenesis analysis.
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PMID:Hybrid E. coli--Mitochondrial ribonuclease P RNAs are catalytically active. 1689 20

The RNase P RNA (rnpB) and protein (rnpA) genes were identified in the two Aquificales Sulfurihydrogenibium azorense and Persephonella marina. In contrast, neither of the two genes has been found in the sequenced genome of their close relative, Aquifex aeolicus. As in most bacteria, the rnpA genes of S. azorense and P. marina are preceded by the rpmH gene coding for ribosomal protein L34. This genetic region, including several genes up- and downstream of rpmH, is uniquely conserved among all three Aquificales strains, except that rnpA is missing in A. aeolicus. The RNase P RNAs (P RNAs) of S. azorense and P. marina are active catalysts that can be activated by heterologous bacterial P proteins at low salt. Although the two P RNAs lack helix P18 and thus one of the three major interdomain tertiary contacts, they are more thermostable than Escherichia coli P RNA and require higher temperatures for proper folding. Related to their thermostability, both RNAs include a subset of structural idiosyncrasies in their S domains, which were recently demonstrated to determine the folding properties of the thermostable S domain of Thermus thermophilus P RNA. Unlike 16S rRNA phylogeny that has placed the Aquificales as the deepest lineage of the bacterial phylogenetic tree, RNase P RNA-based phylogeny groups S. azorense and P. marina with the green sulfur, cyanobacterial, and delta/epsilon proteobacterial branches.
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PMID:Thermostable RNase P RNAs lacking P18 identified in the Aquificales. 1700 27

The natural trans-acting ribozyme RNase P RNA (RPR) is composed of two domains in which the catalytic (C-) domain mediates cleavage of various substrates. The C-domain alone, after removal of the second specificity (S-) domain, catalyzes this reaction as well, albeit with reduced efficiency. Here we provide experimental evidence indicating that efficient cleavage mediated by the Escherichia coli C-domain (Eco CP RPR) with and without the C5 protein likely depends on an interaction referred to as the "P6-mimic". Moreover, the P18 helix connects the C- and S-domains between its loop and the P8 helix in the S-domain (the P8/ P18-interaction). In contrast to the "P6-mimic", the presence of P18 does not contribute to the catalytic performance by the C-domain lacking the S-domain in cleavage of an all ribo model hairpin loop substrate while deletion or disruption of the P8/ P18-interaction in full-size RPR lowers the catalytic efficiency in cleavage of the same model hairpin loop substrate in keeping with previously reported data using precursor tRNAs. Consistent with that P18 is not required for cleavage mediated by the C-domain we show that the archaeal Pyrococcus furiosus RPR C-domain, which lacks the P18 helix, is catalytically active in trans without the S-domain and any protein. Our data also suggest that the S-domain has a larger impact on catalysis for E. coli RPR compared to P. furiosus RPR. Finally, we provide data indicating that the absence of the S-domain and P18, or the P8/ P18-interaction in full-length RPR influences the charge distribution near the cleavage site in the RPR-substrate complex to a small but reproducible extent.
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PMID:Critical domain interactions for type A RNase P RNA catalysis with and without the specificity domain. 2950 61

RNase P, an essential ribonucleoprotein enzyme is involved in processing 5' end of pre-tRNA molecules. All bacterial RNase P holoenzymes, including that of Mycobacterim tuberculosis, an important human pathogen contain a catalytically active RNA subunit and a protein subunit. However, the mycobacterial RNA is larger than typical bacterial RNase P RNAs. It contains the essential core structure and many unique features in the peripheral elements. In the current study, an extensive mutational analysis was performed to analyze the function of the unique features in P12, P15.A, P18 and P19 helices in the mycobacterial RNase P RNA. The study demonstrates that P12 interacts with monovalent and divalent ions and is important for the function of mycobacterial holoenzyme. The helices, P15.A and P18 appear to interact with ammonium and magnesium ions, respectively. P19 is involved in the thermostability of the RNA component as well as interaction with ammonium ions. A homology model of M. tuberculosis RNase P RNA indicates many new inter- and intra-helical interactions. The significance of the unique interactions paves way towards understanding the differential functioning of M. tuberculosis RNase P RNA, for exploring specific inhibition of the same in the pathogen to contain infection.
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PMID:Insight into the functional role of unique determinants in RNA component of RNase P of Mycobacterium tuberculosis. 3008 31