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Query: UNIPROT:P06889 (
Mol
)
630,302
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Ribonuclease P (
RNase P
) is a ribonucleoprotein responsible for the endonucleolytic cleavage of the 5'-termini of tRNAs. Ribonuclease MRP (RNase MRP) is a ribonucleoprotein that has the ability to cleave both mitochondrial RNA primers presumed to be involved in mitochondrial DNA replication and rRNA precursors for the production of mature rRNAs. Several lines of evidence suggest that these two ribonucleoproteins are related to each other, both functionally and evolutionarily. Both of these enzymes have activity in the nucleus and mitochondria. Each cleave their RNA substrates in a divalent cation dependent manner to generate 5'-phosphate and 3'-OH termini. In addition, the RNA subunits of both complexes can be folded into a similar secondary structure. Each can be immunoprecipitated from mammalian cells with Th antibodies. In yeast, both have been found to share at least one common protein. This review will discuss some of the recent advances in our understanding of the structure, function and evolutionary relationship of these two enzymes in the yeast, Saccharomyces cerevisiae.
Mol
Biol Rep
PMID:The yeast, Saccharomyces cerevisiae, RNase P/MRP ribonucleoprotein endoribonuclease family. 890 93
A brief review of the genetic studies on
ribonuclease P
(
RNase P
) from Escherichia coli is presented. Temperature-sensitive mutants of E. coli defective in tRNA processing were isolated by screening cells which were unable to synthesize a suppressor tRNA at restrictive temperature. Structural analysis of accumulated tRNA precursors showed that the isolated mutants were defective in
RNase P
activity. Analyses of the mutants revealed that the enzyme is essential for the synthesis of all tRNA molecules in cells and that the enzyme consists of two subunits. Analyses of the isolated mutants revealed a possible domain structure of the RNA subunit of the enzyme.
Mol
Biol Rep
PMID:Genetic analysis of the structure and function of RNase P from E. coli. 890 96
Molecular investigations in mitochondria of higher plants have to take in account the complicated genomic structure of these organelles and their complex mode of gene expression. Recently tRNA processing activities and particularly
RNase P
-like activities have been described for mitochondria of mono- and dicot plants. The determined biochemical characteristics of these plant mitochondrial tRNA processing enzymes now allow a comparison to the bacterial prototype from which they evolved. The substrate specificity of the plant mitochondrial
RNase P
in particular has unique selection parameters distinct from the E. coli
RNase P
.
Mol
Biol Rep
PMID:Plant mitochondrial RNase P. 890 3
Eukaryotic
ribonuclease P
(
RNase P
) enzymes require both RNA and protein subunits for activity in vivo and in vitro. We have undertaken an analysis of the complex RNA subunit of the nuclear holoenzyme in an effort to understand its structure and its similarities to and differences from the bacterial ribozymes. Phylogenetic analysis, structure-sensitive RNA footprinting, and directed mutagenesis reveal conserved secondary and tertiary structures with both strong similarities to the bacterial consensus and distinctive features. The effects of mutations in the most highly conserved positions are being used to dissect the functions of individual subdomains.
Mol
Biol Rep
PMID:Structure-function analysis in nuclear RNase P RNA. 890 4
Ribonuclease P (
RNase P
) is a key enzyme involved in tRNA biosynthesis. It catalyses the endonucleolytic cleavage of nearly all tRNA precursors to produce 5'-end matured tRNA.
RNase P
activity has been found in all organisms examined, from bacteria to mammals. Eubacterial RNase RNA is the only known RNA enzyme which functions in trans in nature. Similar behaviour has not been demonstrated in
RNase P
enzymes examined from archaebacteria or eukaryotes. Characterisation of
RNase P
enzymes from more diverse eukaryotic species, including the slime mold Dictyostelium discoideum, is useful for comparative analysis of the structure and function of eukaryotic
RNase P
.
Mol
Biol Rep
PMID:The RNase P of Dictyostelium discoideum. 890
Modification interference is a powerful method to identify important functional groups in RNA molecules. We review here recent developments of techniques to screen for chemical modifications that interfere with (i) binding of (pre-)tRNA to bacterial
RNase P
RNA or (ii) pre-tRNA cleavage by this ribozyme. For example, two studies have analyzed positions at which a substitution of sulfur for the pro-Rp oxygen affects tRNA binding [1] or catalysis [2]. The results emphasize the functional key role of a central core element present in all known
RNase P
RNA subunits. The four sulfur substitutions identified in one study [2] to inhibit the catalytic step also interfered with binding of tRNA to E. coli
RNase P
RNA [1]. This suggests that losses in binding energy due to the modification at these positions affect the enzyme-substrate and the enzyme-transition state complex. In addition, the two studies have revealed, for the first time, sites of direct metal ion coordination in
RNase P
RNA. The potentials, limitations and interpretational ambiguities of modification interference experiments as well as factors influencing their outcome are discussed.
Mol
Biol Rep
PMID:Recent approaches to probe functional groups in ribonuclease P RNA by modification interference. 890 5
RNase P
consists of both protein and RNA subunits in all organisms and organelles investigated so far, with the exception of chloroplasts and plant nuclei where no enzyme-associated RNA has been detected to date. Studies on substrate specificity revealed that cleavage by plant nuclear
RNase P
is critically dependent on a complete and intact structure of the substrate. No clearcut answer is yet possible regarding the order of processing events at the 5' or 3' end of tRNAs in the case of nuclear or chloroplast processing enzymes.
RNase P
from a phylogenetically ancient photosynthetic organelle will be discussed in greater detail: The enzyme from the Cyanophora paradoxa cyanelle is the first
RNase P
from a photosynthetic organelle which has been shown to contain an essential RNA subunit. This RNA is strikingly similar to its counterpart from cyanobacteria, yet it lacks catalytic activity. Properties of the holoenzyme suggest an intermediate position in RNA enzyme evolution, with an Eukaryotic-type, inactive RNA and a prokaryotic-type small protein subunit. The possible presence of an RNA component in
RNase P
from plant nuclei and modern chloroplasts will be discussed, including a critical evaluation of some criteria that have been frequently applied to elucidate the subunit composition of
RNase P
from different organisms.
Mol
Biol Rep
PMID:Ribonuclease P from plant nuclei and photosynthetic organelles. 890 1
Chloroplasts of land plants have an active transfer RNA processing system, consisting of an
RNase P
-like 5' endonuclease, a 3' endonuclease, and a tRNA:CCA nucleotidyltransferase. The specificity of these enzymes resembles more that of their eukaryotic counterparts than that of their cyanobacterial predecessors. Most strikingly, chloroplast
RNase P
activity almost certainly resides in a protein, rather than in an RNA.protein complex as in Bacteria, Archaea, and Eukarya. The chloroplast enzyme may have evolved from a preexisting chloroplast NADP-binding protein. Chloroplast
RNase P
cleaves pre-tRNA by a reaction mechanism in which at least one of the Mg2+ ions utilized by the bacterial ribozyme
RNase P
is replaced by an amino acid side chain.
Mol
Biol Rep
PMID:Structure, mechanism and evolution of chloroplast transfer RNA processing systems. 890 2
TransferRNA recognition was used as leit-motiv in the illustration of possible links between a hypothetical primordial RNA world and the contemporary DNA world. In an RNA world, 'proto-tRNA' could have functioned as replication origin and as primitive telomere. Possibly, this primitive structure is preserved in a 'universal substrate' for modern tRNA-specific enzymes. The combination of acceptor stem and T arm (plus a linker) was finally revealed as sufficient for the recognition by prokaryotic and eukaryotic
RNase P
, as well as other tRNA enzymes. In modern life forms, a tRNA-like element in viral RNAs still serves as replication origin, and furthermore, the recognition of similar structures as cryptic promoters is universally conserved for template-dependent RNA polymerases. Another common property of modern polymerases is their high, but clearly limited and condition-dependent substrate specificity. Very likely, also substrate recognition by primitive polymerases was not more stringent, and this lead to the occurrence of mixed nucleic acids as intermediates in the transition of genomic RNA to contemporary genomic DNA.
Mol
Biol Rep
PMID:Enzymatic RNA synthesis and RNase P. Evolutionary aspects. 890 7
Mature tRNAs are remarkably similar in all cells. However, the primary transcripts from tRNA genes can vary considerably due to differences in gene organization.
RNase P
must be able to recognize the elements that are common to all tRNA precursors to accurately remove the 5'-leader sequences.
Mol
Biol Rep
PMID:Transfer RNA gene organization and RNase P. 890 8
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