Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

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.
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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 isolated a weak UGA suppressor of phage T4 tRNA(Gly) in which the anticodon is changed from UCC to UCA. Two secondary mutants lacking suppressor activity are atypical in accumulating tRNA(Gly). Both mutations change the T stem of the cloverleaf model. One involved a G to A change at the 5' base position of the middle base-pair; the second involves a C to U change at a constant base position next to the T loop. The precursor RNAs of the mutants were cleaved in vitro with the catalytic RNA subunit of RNase P. Relative to normal precursor RNA, the precursor mutated at the middle base-pair position of the T stem was cleaved more rapidly, whereas the precursor mutated at the base-pair position next to the T loop was cleaved more slowly.
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PMID:Suppressor and novel mutants of bacteriophage T4 tRNA(Gly). 243 21

We propose a new model for the secondary structure of the M1 RNA component of E. coli RNase P which is based on significant sequence homologies with parts of the E. coli 16 S rRNA. A large domain of the new model resembles closely the secondary structure of the tRNA binding center of 16 S rRNA. We suggest that this domain of M1 RNA when functioning as a ribozyme binds the mature part of the precursor tRNA.
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PMID:Similarities between a predicted secondary structure for the M1 RNA ribozyme and the tRNA binding center of 16 S rRNA from E. coli. 244 Jul 26

Experiments were conducted to investigate structural features of the aminoacyl stem region of precursor histidine tRNA critical for the proper cleavage by the catalytic RNA component of RNase P that is responsible for 5' maturation. Histidine tRNA was chosen for study because tRNAHis has an 8 base pair instead of the typical 7-base pair aminoacyl stem. The importance of the 3' proximal CCA sequence in the 5'-processing reaction was also investigated. Our results show that the tRNAHis precursor patterned after the natural Bacillus subtilis gene is cleaved by catalytic RNAs from B. subtilis or Escherichia coli, leaving an extra G residue at the 5'-end of the aminoacyl stem. Replacing the 3' proximal CCA sequence in the substrate still allowed the catalytic RNA to cleave at the proper position, but it increased the Km of the reaction. Changing the sequence of the 3' leader region to increase the length of the aminoacyl stem did not alter the cleavage site but reduced the reaction rate. However, replacing the G residue at the expected 5' mature end by an A changed the processing site, resulting in the creation of a 7-base pair aminoacyl stem. The Km of this reaction was not substantially altered. These experiments indicate that the extra 5' G residue in B. subtilis tRNAHis is left on by RNase P processing because of the precursor's structure at the aminoacyl stem and that the cleavage site can be altered by a single base change. We have also shown that the catalytic RNA alone from either B. subtilis or E. coli is capable of cleaving a precursor tRNA in which the 3' proximal CCA sequence is replaced by other nucleotides.
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PMID:Structural requirements for processing of synthetic tRNAHis precursors by the catalytic RNA component of RNase P. 244 80

The RNA moiety of ribonuclease P from Escherichia coli (M1 RNA) has been photoreacted with 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) and long-wave UV light (320-380 nm) in a buffer containing 60 mM Mg2+, where the RNA moiety acts as a true catalyst of tRNA processing. Limited specific digestion and two-dimensional gel electrophoresis yield fragments cross-linked by HMT. By photoreversal of the isolated cross-linked fragments and enzymatic sequencing of the fragments, the positions of the cross-links have been elucidated. This method allows us to locate the cross-link to +/- 15 nucleotides. Further assignments of the exact locations of the cross-links have been made on the basis of the known photoreactivity of the psoralen with different bases. Nine unique cross-links have been isolated in the M1 RNA including four long-range interactions. The short-range interactions are discussed here in detail.
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PMID:Structure of M1 RNA as determined by psoralen cross-linking. 245 May 74

We have constructed a plasmid expressing E. coli M1 RNA, the catalytic RNA subunit of ribonuclease P, under the control of a phage T7 promoter. The active M1 RNA species synthesized in vitro by T7 RNA polymerase from this vector was reacted with the tRNA(Gln) - tRNA(Leu) precursor RNA (Band K) encoded by phage T4. Only the tRNA(Leu) moiety of this dimeric precursor RNA contains the 3' terminal C-C-A sequence common to all tRNAs. We observed that protein-free M1 RNA was capable of processing the precursor RNA at the 5' ends of both tRNA tRNA sequences. The rate of cleavage of the tRNA(Gln) sequence was more strongly dependent on [Mg2+] than that of tRNA(Leu), increasing severalfold between 100 and 500 mM Mg2+, conditions under which the rate of cleavage at the tRNA(Leu) sequence was constant.
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PMID:Dependence of M1 RNA substrate specificity on magnesium ion concentration. 245 26

We have studied the efficiency of suppression by tRNA suppressors in vivo in strains of Escherichia coli that harbor a mutation in the rnpA gene, the gene for the protein component (C5) of RNase P, and in strains that carry several different alleles of the rnpB gene, the gene for the RNA component (M1) of RNase P. Depending on the genetic background, different efficiencies of suppression by the various tRNA suppressors were observed. Thus, mutations in rnpA have separable and distinct effects from mutations in rnpB on the processing of tRNA precursors by RNase P. In addition, the efficiency of suppression by several derivatives of E. coli tRNA(Tyr) Su3 changed as the genetic background was altered.
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PMID:Differential effects of mutations in the protein and RNA moieties of RNase P on the efficiency of suppression by various tRNA suppressors. 246 97

Proposals that an RNA-based genetic system preceded DNA, stem from the ability of RNA to store genetic information and to promote simple catalysis. However, to be a valid basis for the RNA world, RNA catalysis must demonstrate or be related to intrinsic chemical properties which could have existed in primordial times. We analyze this question by first classifying RNA catalysis and related processes according to their mechanism. We define: (A) the disjunct nucleophile class which leads to 5'-phosphates. These include Group I and II intron splicing, nuclear mRNA splicing and RNase P reactions. Although Group I introns and its excision mechanism is likely to have existed in primordial times, present-day examples have arisen independently in different phyla much more recently. Comparative methodology indicates that RNase P catalysis originated before the divergence of the major kingdoms. In addition, all disjunct nucleophile reactions can be interrelated by a proposed mechanism involving a distant 2-OH nucleophile. (B) the conjunct nucleophile class leading to 3'-phosphates. This class is composed of self-cleaving RNAs found in plant viruses and the newt. We propose that tRNA splicing is related to this mechanism rather than the previous one. The presence of introns in tRNA genes of eukaryotes and archaebacteria supports the idea that tRNA splicing predates the divergence of these cell types.
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PMID:The relationship between RNA catalytic processes. 246 24

RNase P and ribosomes must interact with similar substrate molecules, tRNA precursors in the case of RNase P and aminoacyl-, peptidyl- or free tRNAs in the case of ribosomes. In order to compare the substrate recognition mechanisms between ribosomes and RNase P, protein synthesis inhibitors have been assayed for their effect on the catalytic activity of the RNA component of Escherichia coli RNase P (M1 RNA). Puromycin has an inhibitory effect that could be related to similar substrate recognition mechanisms by rRNA in the ribosome and by M1 RNA in RNase P.
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PMID:Protein synthesis inhibitors and catalytic RNA. Effect of puromycin on tRNA precursor processing by the RNA component of Escherichia coli RNase P. 246 23

Ribonuclease P (RNase P) RNA is the catalytic moiety of the ribonucleoprotein enzyme that removes precursor sequences from the 5' ends of pre-transfer RNAs in eubacteria. Phylogenetic variation according to recently proposed secondary structure models was used to identify structural elements of the RNase P RNA that are dispensable for catalysis. A simplified RNase P RNA that consists only of evolutionarily conserved features was designed, synthesized, and characterized. Although the simplified RNA (Min 1 RNA) is only 263 nucleotides in length, in contrast to the 354 to 417 nucleotides of naturally occurring RNase P RNAs, its specificity of pre-tRNA cleavage is identical to that of the native enzymes. Moreover, the catalytic efficiencies of the Min 1 RNA and the native RNA enzymes are similar. These results focus the search for the catalytic elements of RNase P RNAs to their conserved structure.
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PMID:The design and catalytic properties of a simplified ribonuclease P RNA. 247 71


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