Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: EC:3.1.26.5 (
RNase P
)
1,348
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The biosynthesis of some mitochondrial enzymes requires contributions of both the mitochondrial and nuclear genomes. The ribonucleoprotein enzyme Ribonuclease P (
RNase P
) is composed of a mitochondrial encoded RNA and nuclear coded protein in many yeasts, including C. glabrata. We have determined that there are at least two sites of transcription initiation that contribute to the expression of the mitochondrial
RNase P
RNA. A nonanucleotide promoter sequence is located upstream of the initiator tRNA while the other site of initiation of transcription is at an undetermined upstream site. An analysis of the transcripts from the region of the
RNase P
gene demonstrates directly that the
RNase P
RNA is present in large primary transcripts and located between the precursors to the initiator tRNAf(
Met
) and tRNA(Pro) genes. Thus this enzyme subunit is synthesized with some of its substrate tRNAs. An activity with cleavage site specificity like a previously described endonuclease that cleaves near the 3' end of tRNAs,
RNase P
activity and one or more additional endonucleases or exonucleases not described previously are required to convert the primary transcript to its final functional RNAs.
...
PMID:RNase P RNA in Candida glabrata mitochondria is transcribed with substrate tRNAs. 195 82
Modified bases were introduced into pre-tRNAs during in vitro RNA synthesis or by chemical modification. These RNAs were used as substrates for the catalytic M1 RNA and the
RNase P
holoenzyme from Schizosaccharomyces pombe. The synthetic approach permitted the insertion of 100% m7GTP into pre-tRNAs and this resulted in complete inhibition of the specific 5' processing reactions. Partially modified RNAs were obtained by chemical modifications of purines and uridines in the pre-tRNAs. This allowed detailed analyses of specific bases excluded in the products. With pre-tRNA(Ser) and initiator pre-tRNA(
Met
), strong effects were observed in the T arm and weaker effects in the anticodon stem. Only minor base exclusions were detected in the acceptor stem of pre-tRNA(Ser) and in the D arm of pre-tRNA(
Met
).
...
PMID:Substrate recognition by RNase P and by the catalytic M1 RNA: identification of possible contact points in pre-tRNAs. 234 11
Induction of GCN4 translation in amino acid-starved cells involves the inhibition of initiator tRNA(
Met
) binding to eukaryotic translation initiation factor 2 (eIF2) in response to eIF2 phosphorylation by protein kinase GCN2. It was shown previously that GCN4 translation could be induced independently of GCN2 by overexpressing a mutant tRNA(AAC)(Val) (tRNA(Val*)) or the RNA component of RNase MRP encoded by NME1. Here we show that overexpression of the tRNA pseudouridine 55 synthase encoded by PUS4 also leads to translational derepression of GCN4 (Gcd(-) phenotype) independently of eIF2 phosphorylation. Surprisingly, the Gcd(-) phenotype of high-copy-number PUS4 (hcPUS4) did not require PUS4 enzymatic activity, and several lines of evidence indicate that PUS4 overexpression did not diminish functional initiator tRNA(
Met
) levels. The presence of hcPUS4 or hcNME1 led to the accumulation of certain tRNA precursors, and their Gcd(-) phenotypes were reversed by overexpressing the RNA component of
RNase P
(RPR1), responsible for 5'-end processing of all tRNAs. Consistently, overexpression of a mutant pre-tRNA(Tyr) that cannot be processed by
RNase P
had a Gcd(-) phenotype. Interestingly, the Gcd(-) phenotype of hcPUS4 also was reversed by overexpressing LOS1, required for efficient nuclear export of tRNA, and los1Delta cells have a Gcd(-) phenotype. Overproduced PUS4 appears to impede 5'-end processing or export of certain tRNAs in the nucleus in a manner remedied by increased expression of
RNase P
or LOS1, respectively. The mutant tRNA(Val*) showed nuclear accumulation in otherwise wild-type cells, suggesting a defect in export to the cytoplasm. We propose that yeast contains a nuclear surveillance system that perceives defects in processing or export of tRNA and evokes a reduction in translation initiation at the step of initiator tRNA(
Met
) binding to the ribosome.
...
PMID:Defects in tRNA processing and nuclear export induce GCN4 translation independently of phosphorylation of the alpha subunit of eukaryotic translation initiation factor 2. 1071 74
We have previously reported that the catalytic RNA subunit of
RNase P
of Escherichia coli (M1 RNA) cleaves Drosophila initiator methionine tRNA (tRNA(
Met
)i) within the mature tRNA sequence to produce specific fragments. This cleavage was dependent on the occurrence of an altered conformation of the tRNA substrate. We call this further cleavage hyperprocessing. In the present paper, to search for another tRNA that can be hyperprocessed in vitro, we used total mature tRNAs from Drosophila as substrates for the in vitro M1 RNA reaction. We found that some tRNAs can be hyperprocessed by M1 RNA and that two such tRNAs are an alanine tRNA and a histidine tRNA. Using mutant substrates of these tRNAs, we also show that the hyperprocessing by M1 RNA is dependent on the occurrence of altered conformations of these tRNAs. The altered conformations were very similar to that of tRNA(
Met
)i. We show here that M1 RNA can be used as a powerful tool to detect the alternative conformation of tRNAs. The relationship between these hyperprocessing reactions and stability of the tRNA structure will also be discussed.
...
PMID:In vitro hyperprocessing of Drosophila tRNAs by the catalytic RNA of RNase P the cloverleaf structure of tRNA is not always stable? 1090 12
We have previously reported that the catalytic RNA subunit of
ribonuclease P
(
RNase P
) of Escherichia coli (M1 RNA) cleaves Drosophila initiator methionine tRNA (tRNA(i)
Met
), alanine tRNA (tRNA(Ala)) and histidine tRNA (tRNA(His)) within the mature tRNA sequences to produce specific fragments. We call this further cleavage hyperprocessing. These cleavages were dependent on the occurrence of altered conformations of the tRNAs. Here, we found that the
RNase P
RNA of Bacillus subtilis can hyperprocess these three tRNAs at the same sites as does M1 RNA. The hyperprocessing activity may probably be common feature for Bacterial
RNase P
RNAs.
...
PMID:In vitro hyperprocessing of tRNAs by Bacillus subtilis ribonuclease P RNA. 1283 38
Since the discovery of catalytic RNA molecules (ribozymes), intense research has been devoted to understand their structure and activity. Among RNA molecules, the large ribozymes, namely group I and group II introns and
RNase P
, are of special importance. The first two ribozymes are known for their ability to perform self-splicing while
RNase P
is responsible for the 5'-end maturation of tRNA in bacteria, archea, and eukaryotes. All three groups of ribozymes show a significant requirement for metal ions in order to establish the active tertiary structure that enables catalysis. The primary role of both monovalent and divalent metal ions is to screen the negative charge associated with the phosphate sugar backbone, but the metal ions also play an active role in catalysis. Biochemical and biophysical investigations, supported by recent findings from X-ray crystal structures, allow clarifying and rationalizing both the structural and catalytic roles of metal ions in large ribozymes. In particular, the "two-metal-ion mechanism", describing how metal ions in the active center take part in catalysis, has been largely corroborated.
Met
Ions Life Sci 2011
PMID:Multiple roles of metal ions in large ribozymes. 2201 Feb 73
The trancription of a cloned trnV1-trnN1-trnR1 cluster from Euglena gracilis chloroplast (ct) DNA and the processing of a tRNA(Val)-tRNA(Asn)-tRNA(Arg) polycistronic precursor were studied in a spinach ct transcription extract. A soluble ct RNA polymerase selectively transcribes the trnV1-trnN1-trnR1-trnL1 locus in the EcoG fragment from the Euglena ct genome. Restriction enzyme modified templates and RNA fingerprint analysis were used to confirm that the tRNA genes were correctly transcribed. The tRNA(Val)-tRNA(Asn)-tRNA(Arg) polycistronic precursor transcribed by RNA polymerase III in a HeLa cell extract was used as a substrate to demonstrate that a ct tRNA precursor molecule is correctly processed by the ct tRNA processing enzymes. The oligonucleotide pattern of tRNAs processed in vitro from the tRNA(Val)-tRNA(Asn)-RNA(Arg) polycistronic precursor is indistinguishable from tRNA(Val), tRNA(Asn) and tRNA(Arg) transcribed by the ct RNA polymerase and processed in the ct transcription extract. The 3'-CCAOH is added to the tRNAs by a 3' nucleotidyltransferase after correct processing of the 3' terminus. Correct pseudouridylation was demonstrated for uridine residues in a tRNA(
Met
) m molecule transcribed from a spinach ct trnM1 locus. Thus, the enzymatic activities involved in tRNA biosynthesis in vitro include DNA-dependent (tDNA) RNA polymerase, a 5'-processing activity (
RNase P
-like), a 3'-exonuclease, an endoribonuclease involved in 3'-tRNA maturation, a tRNA nucleotidyltransferase, and pseudouridylate synthetase.
...
PMID:Accurate processing and pseudouridylation of chloroplast transfer RNA in a chloroplast transcription system. 2431 Mar 5
Although lead(II) is naturally not associated with nucleic acids, this metal ions has been applied with DNA and RNA in various contexts. Pb2+ is an excellent hydrolytic metal ion for nucleic acids, which is why it is mainly used as probing agent for secondary structure and to determine metal ion binding sites both in vitro and in vivo. A further application of lead(II) is in structural studies, i.e., NMR, but also in X-ray crystallography, mostly using this heavy metal to solve the phase problem in the latter method. The structures of tRNAPhe,
RNase P
, HIV-1 DIS, and the leadzyme are discussed here in detail. A major part of this review is devoted to the cleavage properties of lead(II) with RNA because of its excellence in catalyzing phosphodiester cleavage. Metal ion binding sites in large naturally occurring ribozymes are regularly determined by Pb2+ cleavage, and also in the in vitro selected socalled leadzyme, this metal ion is the decisive key to backbone cleavage at a specific site. Lead(II) was used in the first in vitro selection that yielded a catalytic DNA, i.e., the DNAzyme named GR5. Next to the GR5, the so-called 8-17E is the second most prominent DNAzyme today. Derivatives of these two lead(II)-dependent DNAzymes, as well as the G-quadruplex forming PS2.M have been applied to detect lead(II) in the lower nanomolar range not only in the test tube but also in body fluids. Due to the toxicity of lead(II) for living beings, this is a highly active research field. Finally, further applications of lead(II)-dependent DNAzymes, e.g., in the construction of nanocomputers, are also discussed.
Met
Ions Life Sci 2017 04 10
PMID:The Role of Lead(II) in Nucleic Acids. 2873 5
