Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:3.1.26.5 (RNase P)
 1,348 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In a temperature-sensitive mutant of E. coli defective in tRNA biosynthesis, many tRNA precursors, including monomeric and multimeric forms, accumulate. Some of the multimeric precursors contain three or more tRNA sequences within a molecule. These large precursors were cleaved by cell extracts first into intermediate size pieces which were subsequently processed by RNase P. On the basis of heat stability of mutant cell extracts, the endonuclease responsible for the initial cleavage appears to be distinct from RNase P and is designated RNase O. One of the monomeric precursors was shown to be processed first by RNase P and the product subsequently cleaved further into a smaller molecule. The nuclease responsible for this second cleavage also appears to be distinct from RNase P and is designated RNase Q. The functions of these nucleases are sequential in the trimming process with respect to that of RNase P; RNase O works prior to RNase P and RNase Q after RNase P but in both cases, not vice versa.
Proc Natl Acad Sci U S A 1975 Sep
PMID:Sequential processing of precursor tRNA molecules in Escherichia coli. 110 44

Ribonuclease P from Escherichia coli can cleave RNAs in simple, hydrogen-bonded complexes of two oligoribonucleotides that resemble the aminoacyl stem and 5' leader sequence of tRNA precursors. RNase P from human (HeLa) cells cannot catalyze the cleavage in vitro of the 5'-proximal oligoribonucleotide that contains the leader sequence in such simple complexes but can do so when the 3'-proximal oligoribonucleotide (external guide sequence) is altered to resemble three-quarters of a tRNA molecule. In such a complex, the efficiency of cleavage of the mRNA for chloramphenicol acetyltransferase, as the 5'-proximal oligoribonucleotide, depends on the structural details of the external guide sequence and on the choice of target site within the mRNA. The presence of the appropriately designed external guide sequence in cells in tissue culture reduces chloramphenicol acetyltransferase activity and the level of the corresponding intact mRNA in the cells. Thus, it appears that the use of such external guide sequences may provide a general technique for gene inactivation.
Proc Natl Acad Sci U S A 1992 Sep 01
PMID:Targeted cleavage of mRNA by human RNase P. 138 5

A study was made of the cleavage by M1 RNA and RNase P of a non-tRNA precursor that can serve as a substrate for RNase P from Escherichia coli, namely, the precursor to 4.5 S RNA (p4.5S). The overall efficiency of cleavage of p4.5S by RNase P is similar to that of wild-type tRNA precursors. However, unlike the reaction with wild-type tRNA precursors, the reaction catalyzed by the holoenzyme with p4.5S as substrate has a much lower Km value than that catalyzed by M1 RNA with the same substrate, indicating that the protein subunit plays a crucial role in the recognition of p4.5S. A model hairpin substrate, based on the sequence of p4.5S, is cleaved with greater efficiency than the parent molecule. The 3'-terminal CCC sequence of p4.5 S may be as important for cleavage of this substrate as the 3'-terminal CCA sequence is for cleavage of tRNA precursors.
J Mol Biol 1991 Sep 05
PMID:Kinetics of the processing of the precursor to 4.5 S RNA, a naturally occurring substrate for RNase P from Escherichia coli. 171 93

We recently showed that RNase III can process a small stable RNA, precursor 10Sa RNA, that accumulates in an rne (RNase E) strain at non-permissive temperatures. Precursor 10Sa (p10Sa) RNA is processed to 10Sa RNA in two steps, the first step is catalyzed by RNase III in the presence of Mn2+ but not Mg2+. It was shown that RNase III cosediments with membrane preparation from wild type as well as RNase III overexpressing cells. However, the possibility of membrane preparation contamination with ribosomes could not be ruled out. Here we show that RNase III, E and P are not associated with ribosomes. E. coli cells were opened either by alumina grinding or by sonication and fractionated into cytosolic and pellet fractions. The characterization of membrane preparations was done by assaying NADH oxidase, a bona fide membrane enzyme. Ribosomes prepared by alumina grinding were found to be contaminated with small fragments of membrane which contained RNase III activity. RNase III and NADH oxidase activities were present in the ribosomal preparations which could be solubilized by reagents that dissolve the inner membrane. Isopycnic sucrose gradient centrifugation of the membrane and ribosomal preparations also confirmed that RNase III fractionated with the inner membrane. Similarly RNase P activity was found in the corresponding fractions when isopycnic centrifugation of membrane and ribosome preparations was carried out. RNase E activity was also found to be present mostly in the post-ribosomal supernatant. These findings show that RNase III, E and P are not ribosomal enzymes.
Biochem Int 1991 Sep
PMID:RNA processing enzymes RNase III, E and P in Escherichia coli are not ribosomal enzymes. 172 76

One addition mutation and several small deletion mutations have been created in vitro at a unique site in the gene coding for M1 RNA, the RNA subunit of Escherichia coli RNase P. The mutant genes exhibit a wide range of efficiencies in complementing another mutant that is thermosensitive for RNase P function in vivo. The transcripts of the mutated genes cleave a precursor tRNA in vitro with efficiencies that parallel their ability to function in the complementation assay in vivo. The secondary structures in solution of the mutant gene transcripts are shown to be different from the parent molecule by probing the structure of the transcripts with ribonuclease T1. A local region of secondary structure, between nucleotides 275 and 295, must be maintained for normal function of M1 RNA.
J Mol Biol 1986 Sep 20
PMID:Site-directed mutagenesis of M1 RNA, the RNA subunit of Escherichia coli ribonuclease P. The effects of an addition and small deletions on catalytic function. 243 55

We have previously described a mitochondrial activity that removes 5' leaders from yeast mitochondrial precursor tRNAs and suggested that it is a mitochondrial RNase P. Here we demonstrate that the cleavage reaction results in a 5' phosphate on the tRNA product and thus the activity is analogous to that of other RNase Ps. A mitochondrial gene called the tRNA synthesis locus encodes an A + U-rich RNA required for this activity in vivo. Two regions of this RNA display sequence similarity to conserved sequences in bacterial RNase P RNAs. This sequence similarity coupled with the analogous activities of the enzymes has led us to conclude that the RNAs are homologous and that the tRNA synthesis locus does code for the mitochondrial RNase P RNA subunit. The smallest and most abundant transcript of the tRNA synthesis locus is 490 nucleotides long. However, during purification of the holoenzyme, RNA is degraded and pieces of the original RNA are sufficient to support RNase P activity in vitro.
Nucleic Acids Res 1989 Sep 12
PMID:Characterization of yeast mitochondrial RNase P: an intact RNA subunit is not essential for activity in vitro. 247 23

Sera from patients with autoimmune diseases often contain antibodies that bind ribonucleoproteins (RNPs). Sera from 30 such patients were found to immunoprecipitate ribonuclease P (RNase P), an RNP enzyme required to process the 5' termini of transfer RNA transcripts in nuclei and mitochondria of eukaryotic cells. All 30 sera also immunoprecipitated the nucleolar Th RNP, indicating that the two RNPs are structurally related. Nucleotide sequence analysis of the Th RNP revealed it was identical to the RNA component of the mitochondrial RNA processing enzyme known as RNase MRP. Antibodies that immunoprecipitated the Th RNP selectively depleted murine and human cell extracts of RNase MRP activity, indicating that the Th and RNase MRP RNPs are identical. Since RNase P and RNase MRP are not associated with each other during biochemical purification, we suggest that these two RNA processing enzymes share a common autoantigenic polypeptide.
Science 1989 Sep 22
PMID:The RNA processing enzyme RNase MRP is identical to the Th RNP and related to RNase P. 247 49

A transfer RNA complete devoid of modified nucleosides was synthesized by in vitro transcription, and some of its properties in aminoacylation and protein synthesis in vitro were studied. For this purpose, a plasmid was constructed which contained a glycine tRNA gene from Mycoplasma mycoides under the promoter of the T7 RNA polymerase, as well as a BstNI restriction site at the 3'-end of the tRNA gene. Cleavage of plasmid DNA with BstNI followed by T7 RNA polymerase transcription in vitro yielded an RNA which was processed with M1 RNA, the catalytic subunit of ribonuclease P, to give a tRNA of mature length. The tRNA synthesized in this manner can be esterified with glycine in vitro, and the rate of aminoacylation is the same as when using the corresponding fully modified glycine tRNA from M. mycoides. Furthermore, in protein synthesis in vitro, the tRNA lacking modified nucleosides was essentially as efficient as the corresponding normal glycine tRNA. However, the Escherichia coli extract used in our protein-synthesizing system introduced one modification, pseudouridine, into the in vitro-synthesized tRNA, and it cannot be excluded that this modification has an essential role in protein synthesis.
J Biol Chem 1988 Sep 25
PMID:Properties of a transfer RNA lacking modified nucleosides. 284 31

The gene encoding the RNA subunit (M1 RNA) of RNAase P (EC 3.1.26.5) from Escherichia coli has been isolated, and its complete nucleotide sequence, including flanking regions, has been determined. The promoter region, similar to others near genes under stringent control, and the site of transcription termination have been identified. The transcript from the gene (M1 RNA) can be drawn in a secondary structure that has approximately 60% G-C base pairs. One hairpin loop of this hypothetical structure has five contiguous nucleotides complementary to invariant nucleotides in the TpsiCG loop of all E. coli tRNAs. The M1 gene, when subcloned in the plasmid pBR325, can be amplified. It directs production of functional M1 RNA. In an E. coli strain thermosensitive for RNAase P function, the size of the gene transcript is the same as in wild-type E. coli, but less mature M1 RNA is made in the mutant cells.
Cell 1982 Sep
PMID:Nucleotide sequence of the gene encoding the RNA subunit (M1 RNA) of ribonuclease P from Escherichia coli. 618 2

The seven tRNA genes clustered in the supB-E region of the Escherichia coli chromosome were transcribed in vitro with purified RNA polymerase, using a restriction fragment from lambda psu degrees 2, a transducing phage carrying the chromosome region, as template. A single major transcript was synthesized, which was about 770 nucleotides long and contained all seven tRNA sequences. The terminal sequences of the transcript were determined and mapped on the DNA sequence of the supB-E region previously determined. The transcription start site is seven base pairs downstream from the Pribnow box sequence, as expected from the DNA sequence analysis and consistent with the findings on the trimeric tRNA precursor (pppG--tRNAMETM-tRNALeu-tRNAGln1) which was detected in an RNase P mutant and shown to be coded for by the supB-E region. Cleavage of the restriction fragment at the -35 region with another restriction endonuclease abolished the template activity of the fragment. Transcription of the supB-E tRNA operon was relatively unaffected by the presence of rho factor. Transcription termination occurs within a region of three bases between positions 770 and 772 from the transcription start site. Immediately upstream from the termination sites, there is a region of 26 nucleotides that could form a stem structure, thereby consistent with the general feature of rho-independent termination sites.
J Biol Chem 1982 Sep 25
PMID:In vitro transcription of the supB-E tRNA operon of Escherichia coli. Characterization of transcription products. 628 82


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