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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)
We synthesized two types of chimeric RNAs between the catalytic RNA subunit of
RNase P
from Escherichia coli (M1 RNA) and a tRNA precursor (pre-tRNA); one had pre-tRNA at the 3' side to the M1 RNA (M1 RNA-pre-tRNA). The second had pre-tRNA at the 5' side of the M1 RNA (pre-tRNA-M1 RNA). Both molecules were self-cleaving RNAs. The self-cleavage of M1 RNA-pre-tRNA occurred at the normal site (5'-end of mature tRNA sequence) and proceeded under the condition of 10 mM
Mg2+
concentration. This reaction at 10 mM
Mg2+
was an intramolecular reaction (cis-cleavage), while, at 40 mM and 80 mM
Mg2+
, trans-cleavage partially occurred. The self-cleavage rate was strictly affected by the distance between the M1 RNA and the pre-tRNA in the molecule. The self-cleavage of pre-tRNA-M1 RNA occurred mainly at three sites within the mature tRNA sequence. This cleavage did not occur at 10 mM
Mg2+
. Use of M1 RNA-pre-tRNA molecule for the in vitro evolution of M1 RNA is discussed.
...
PMID:Artificial self-cleaving molecules consisting of a tRNA precursor and the catalytic RNA of RNase P. 823 17
A gel retardation assay has been used to examine the kinetic and equilibrium properties of the interaction between C5 protein and M1 RNA in the formation of the
ribonuclease P
holoenzyme from Escherichia coli. The interaction is relatively insensitive to the identity of the monovalent anions present and to pH in the range 7.0-9.0, but it has a more critical requirement for specific monovalent and divalent cations: NH4+, K+,
Mg2+
, Ca2+, and Mn2+ all promote efficient formation of the complex. A positive delta S (+6.4 cal mol-1 deg-1) and a negative delta H (-11.3 kcal mol-1) combine to give a delta G equal to -13.3 kcal mol-1 at 37 degrees C in 0.42 M salt. The binding reaction is sensitive to the concentration of monovalent and divalent cations, with the affinity increasing with increasing ionic strength (delta log Ka/delta log [NH4+] = +2.7 +/- 0.1). The dependence of Kd on the ionic strength and the positive delta S suggests that hydrophobic and stacking interactions contribute significantly to the formation of the
RNase P
holoenzyme.
...
PMID:Kinetic and thermodynamic analysis of RNA-protein interactions in the RNase P holoenzyme from Escherichia coli. 831 59
The ribozyme ribonuclease (RNase) P cleaves precursor transcripts to produce the mature 5'-end of tRNAs. This hydrolysis reaction has a divalent cation requirement that is primarily catalytic, rather than structural;
RNase P
can be considered a metalloenzyme. Kinetic analysis shows that the
RNase P
catalytic mechanism has a cooperative dependence upon
Mg2+
concentration. At least three
Mg2+
ions are required for optimal activity, suggesting a multiple metal ion mechanism. The 2'-OH at the site of substrate cleavage may act as a ligand for a catalytically important
Mg2+
: deoxyribose substitution reduces the apparent number of
Mg2+
bound from three to two and increases the apparent dissociation constant for
Mg2+
from the micromolar to the millimolar range. In addition to these cation effects, the deoxyribose substitution reduces the rate of catalysis by 3400-fold; substitution with 2'-O-methyl at the cleavage site reduces the catalytic rate 10(6)-fold. If we presume no significant conformational effects of the substitutions, these results suggest that the 2'-OH serves as hydrogen-bond donor. The kinetic analysis of the catalytic mechanism is based upon the characterization of the pH dependence of the reaction. There is a hyperbolic (saturable) dependence on hydroxide concentration, with the half-maximal rate achieved at pH 8.0-8.5. The rate of the cleavage step is about 200 min-1 at pH 8.0, which is 500-fold faster than the steady-state parameter kcat.
...
PMID:Multiple magnesium ions in the ribonuclease P reaction mechanism. 849 32
RNase P
, an enzyme essential for tRNA biosynthesis, can be directed to cleave any RNA when the target RNA is in a complex with a short, complementary oligonucleotide called an external guide sequence (EGS).
RNase P
from Escherichia coli can cleave phage lambda N mRNA in vitro or in vivo when the mRNA is in a complex with an EGS. The EGS can either be separate from or covalently linked to M1 RNA, the catalytic RNA subunit of
RNase P
. The requirement for
Mg2+
in the reaction in vitro is lower when the EGS is covalently linked to M1 RNA. Substrates made of DNA can also be cleaved by
RNase P
in vitro in complexes with RNA EGSs. When either kind of EGS construct is used in vivo, burst size of phage lambda is reduced by > or = 40%. Reduction in burst size depends on efficient expression of the EGS constructs. The product of phage lambda gene N appears to function in a stoichiometric fashion.
...
PMID:Cleavage by RNase P of gene N mRNA reduces bacteriophage lambda burst size. 860 Apr 49
Ribonuclease P (
RNase P
) is the enzyme responsible for endonucleolytically separating the 5'-leader sequence from precursor tRNA molecules. In bacteria, and in the nuclei and mitochondria of all eukaryotes studied so far,
RNase P
contains an RNA subunit which is necessary for activity in vitro and in vivo. In contrast, we showed earlier that partially-purified
RNase P
from spinach chloroplasts had physical properties inconsistent with the presence of any RNA. We now report that the properties of the chloroplast enzyme, after 500 to 1500-fold purification, are consistent with enzymatic activity residing in a approximately 70 kDa polypeptide. Gel filtration chromatography on Sephacryl S-200 and S-300 provides a mass for chloroplast
RNase P
of approximately 70 +/- 5 kDa. A single polypeptide of approximately 70-80 kDa can be crosslinked to iodoUMP-substituted pre-tRNA. The labeling intensity of this polypeptide corresponds closely to the peak of
RNase P
activity on Sephacryl S-200 chromatography. Unlike the bacterial ribozyme-type
RNase P
, chloroplast
RNase P
is not a metalloenzyme. We showed previously that phosphodiester bond cleavage by the E. coli RNA enzyme absolutely requires
Mg2+
or Mn2+ coordinated to the pro-Rp oxygen of the scissile phosphodiester phosphate. In contrast, we now find that chloroplast
RNase P
has no such requirement, and can accurately and efficiently cleave pre-tRNA containing an Rp-thio-substitution at the scissile bond. These data are entirely consistent with the hypothesis that
RNase P
in plant chloroplasts is not a ribozyme, but a conventional protein enzyme.
...
PMID:Spinach chloroplast RNase P: a putative protein enzyme. 864 12
Understanding the folding mechanisms of large, highly structured RNAs is important for understanding how these molecules carry out their function. Although models for the three-dimensional architecture of several large RNAs have been constructed, the process by which these structures are formed is only now beginning to be explored. The kinetic folding pathway of the Tetrahymena ribozyme involves multiple intermediates and both
Mg2+
-dependent and
Mg2+
-independent steps. To determine whether this general mechanism is representative of folding of other large RNAs, a study of
RNase P
RNA folding was undertaken. We show, using a kinetic oligonucleotide hybridization assay, that there is at least one slow step on the folding pathway of
RNase P
RNA, resulting in conformational changes in the P7 helix region on the minute timescale. Although this folding event requires the presence of
Mg2+
, the slow step itself does not involve
Mg2+
binding. The P7 and P2 helix regions exhibit distinctly different folding behavior and ion dependence, implying that
RNase P
folding is likely to be a complex process. Furthermore, there are distinct similarities in the folding of
RNase P
RNA from both Bacillus subtilis and Escherichia coli, indicating that the folding pathway may also be conserved along with the final structure. The slow folding kinetics,
Mg2+
-independence of the rate, and existence of intermediates are basic features of the folding mechanism of the Tetrahymena group I intron that are also found in
RNase P
RNA, suggesting these may be general features of the folding of large RNAs.
...
PMID:Slow folding kinetics of RNase P RNA. 871 85
The multiple roles
Mg2+
plays in ribozyme-catalyzed reactions in stabilizing RNA structure, enhancing the affinity of bound substrates, and increasing catalysis are delineated for the RNA component of
ribonuclease P
(
RNase P
RNA) by a combination of steady-state kinetics, transient kinetics, and equilibrium binding measurements. Divalent metal ions cooperatively increase the affinity of Bacillus subtilis
RNase P
RNA for B. subtilis tRNA(Asp) more than 10(3)-fold, consistent with at least two additional magnesium ions binding to the
RNase P
RNA.tRNA complex. Monovalent cations also decrease KD(tRNA) and reduce, but do not eliminate, the dependence on magnesium ions, demonstrating that nonspecific electrostatic shielding is not sufficient to explain the requirement for high salt. Both di- and monovalent cations promote the high affinity of tRNA by forming contacts in the binary complex that reduce the dissociation rate constant for tRNA. Additionally, the hyperbolic dependence of the hydrolytic rate constant on the concentration of magnesium with a K1/2 approximately equal to 36 mM suggests that a third low-affinity divalent metal ion stabilizes the transition state for pre-tRNA cleavage. Furthermore, many (about 100) magnesium ions bind independently to
RNase P
RNA with higher affinity than the K1/2 of any of the functionally characterized magnesium binding sites. Therefore, the magnesium binding sites that have differential affinity in either the "folded" species or binary complex are a small subset of the total number of associated magnesium ions. In summary, the importance of magnesium bound to
RNase P
RNA can be separated functionally into three crucial roles: at least three sites stabilize the folded RNA tertiary structure [Pan. T. (1995) Biochemistry 34, 902-909], at least two sites enhance the formation of complexes of
RNase P
RNA with pre-tRNA or tRNA, and at least one site stabilizes the transition state for pre-tRNA cleavage.
...
PMID:Magnesium ions are required by Bacillus subtilis ribonuclease P RNA for both binding and cleaving precursor tRNAAsp. 875 6
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.
...
PMID:Structure, mechanism and evolution of chloroplast transfer RNA processing systems. 890 2
Ribonuclease P (
RNase P
) is an essential enzyme whose action produces the mature 5' termini of all cellular and organellar transfer RNA molecules. In bacteria, the catalytic subunit of
RNase P
is an RNA molecule which by itself can bind substrate pre-tRNA, select and hydrolyze the correct phosphodiester bond, and release product tRNA. The simple requirements of the reaction-a monovalent cation such as K+ or NH4+ and the divalent cation
Mg2+
(or Mn2+)-have prompted proposals that all aspects of phosphodiester bond hydrolysis might be accomplished by one or more divalent metal cations coordinated to the enzyme or substrate. To precisely localize the ligands of catalytically-involved
Mg2+
, we assayed cleavage by Escherichia coli
RNase P
RNA of pre-tRNA in which specific pro-Rp phosphate oxygens were replaced with sulfur.
RNase P
cleavage was targeted to that bond, at or nearest to the normal cleavage site, at which
Mg2+
or Mn2+ could be coordinated. Single-turnover kinetics demonstrated that the apparent rate constant for the hydrolysis event was determined quantitatively by the affinity of the divalent cation (
Mg2+
or Mn2+) for the atom (O or S) at the pro-Rp position of the scissile phosphodiester bond. We propose a model for pre-tRNA cleavage in which an essential
Mg2+
ion is coordinated directly to the pro-Rp phosphate oxygen and indirectly to two other ligands near the scissile bond: the upstream ribose 2'-hydroxyl and the downstream purine N7. This catalytic
Mg2+
ion most likely positions and deprotonates a water molecule for in-line nucleophilic attack on the scissile bond phosphorus.
...
PMID:Ribonuclease P catalysis requires Mg2+ coordinated to the pro-RP oxygen of the scissile bond. 905 47
Ribonuclease P (
RNase P
) from wheat nuclei has been purified over 1000-fold, using wheat germ extract as starting material and a combination of poly(ethylenglycol) precipitation and column chromatography. The enzyme was shown to be of nuclear origin by its characteristic ionic requirements; for optimum activity it requires 0.5-1.5 mM
Mg2+
, which can be partly replaced by Mn2+. With about 100 kDa, wheat nuclear
RNase P
has the lowest molecular mass reported so far for a eukaryotic
RNase P
. The enzyme has an isoelectric point of 5.0 and a buoyant density of 1.34 g/ml in CsCl, suggesting the presence of a nucleic acid component; it is, however, insensitive against treatment with micrococcal nuclease. Wheat germ
RNase P
requires an intact tertiary structure of the pre-tRNA substrate; its cleavage efficiency is also influenced by the presence of an intron, and by the nature of the 3' terminus of the substrate. The apparent Km and Vmax for an intronless plant pre-tRNA(Tyr) are 10.3 nM and 1.12 fmol/min, respectively.
...
PMID:Partial purification and characterization of nuclear ribonuclease P from wheat. 911 34
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