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Query: UNIPROT:P06889 (Mol)
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The accurate function of C5 protein, the protein component of Escherichia coli RNase P, is uncertain in vivo. A controllable expression system for C5 protein was constructed which can be used to investigate effects of C5 protein on various cellular functions including biosynthesis of RNase P in vivo. The semisynthetic rnpA gene encoding C5 protein was fused to the tac promoter of the pKK223-3 expression vector. This tac promoter expression system produced a high level of C5 protein upon induction with isopropyl-beta-D-thiogalacto-pyranoside. When the overexpressed C5 protein was purified and used for reconstitution of RNase P, the reconstituted enzyme was active. The N-terminal amino acid of the overexpressed C5 protein was leucine specified by the second codon of the rnpA gene. The more controllable expression system was constructed by introducing the lacIq gene into the vector sequence itself.
Mol Cells 1998 Feb 28
PMID:Expression of C5 protein, the protein component of Escherichia coli RNase P, from the tac promoter. 957 38

Eukaryotic precursor (pre)-tRNAs are processed at both ends prior to maturation. Pre-tRNAs and other nascent transcripts synthesized by RNA polymerase III are bound at their 3' ends at the sequence motif UUUOH [3' oligo(U)] by the La antigen, a conserved phosphoprotein whose role in RNA processing has been associated previously with 3'-end maturation only. We show that in addition to its role in tRNA 3'-end maturation, human La protein can also modulate 5' processing of pre-tRNAs. Both the La antigen's N-terminal RNA-binding domain and its C-terminal basic region are required for attenuation of pre-tRNA 5' processing. RNA binding and nuclease protection assays with a variety of pre-tRNA substrates and mutant La proteins indicate that 5' protection is a highly selective activity of La. This activity is dependent on 3' oligo(U) in the pre-tRNA for interaction with the N-terminal RNA binding domain of La and interaction of the C-terminal basic region of La with the 5' triphosphate end of nascent pre-tRNA. Phosphorylation of La is known to occur on serine 366, adjacent to the C-terminal basic region. We show that this modification interferes with the La antigen's ability to protect pre-tRNAiMet from 5' processing either by HeLa extract or purified RNase P but that it does not affect interaction with the 3' end of pre-tRNA. These findings provide the first evidence to indicate that tRNA 5'-end maturation may be regulated in eukaryotes. Implications of triphosphate recognition is discussed as is a role for La phosphoprotein in controlling transcriptional and posttranscriptional events in the biogenesis of polymerase III transcripts.
Mol Cell Biol 1998 Jun
PMID:5' processing of tRNA precursors can Be modulated by the human La antigen phosphoprotein. 958 61

The secondary structure of bacterial RNase P RNA, a ribozyme responsible for the maturation of the 5' end of tRNAs, is well established on the basis of sequence comparison analysis. RNase P RNA secondary structures fall into two types, A and B, which share a common core formed by the assembly of two main folding domains, but differ in their peripheral elements.A revised alignment of 137 available sequences reveals new covariations allowing for the refinement of both types of secondary structures. Phylogenetic evidence is thus provided for the extension of stems P11, P14, P19, P10.1 and P15.1 through further canonical base-pairs or GAellipsisGA mismatches. These refinements led in turn to a new organization of the catalytic core, with coaxial stackings of helices P2 and P19 as well as P1 and P4. New inter-domain tertiary interactions involve loop L9 and helix P1 and loop L8 with helix P4. These features were incorporated into atomic-scale 3D models of RNase P RNA for representatives of each structural type, namely Escherichia coli and Bacillus subtilis. In each model, the juxtaposition of the core helices creates a cradle onto which the pre-tRNA substrate binds with most evolutionarily conserved residues converging towards the cleavage site. The inner cores of both types are stabilized similarly, albeit by different peripheral elements, emphasizing the modular and hierarchical organisation of the architecture of RNase P RNAs. Similarities are thus apparent between the type A modules, P16/P17/P6 and P13/P14, and their type B analogs, P5.1/P15.1 and P10. 1/P10.1a, respectively. Other noteworthy features of these models include compactness and good agreement with published crosslinking data.
J Mol Biol 1998 Jun 19
PMID:Derivation of the three-dimensional architecture of bacterial ribonuclease P RNAs from comparative sequence analysis. 964 60

All mitochondrial tRNAs in kinetoplastid protozoa are encoded in nuclear DNA and transported into the mitochondrion (Simpson et al., Nucl Acids Res 1989;17:5427-5445; Hancock and Hajduk, J Biol Chem 1990;265:19208-19215). It has been proposed that tRNAs in these cells are imported into the mitochondrion as 5'-extended precursors which are processed by a mitochondrial RNase P-like activity (Hancock et al., J Biol Chem 1992;267:23963-23971). We have examined this hypothesis by cloning and sequencing primer extension products of mitochondrial tRNAs from Leishmania tarentolae and Trypanosoma brucei, and have found that these are derived from circularized mature tRNA molecules. We suggest that these molecules are produced by the endogenous RNA ligase activity (Bakalara et al., J Biol Chem 1989;264:18679-18686) either in vivo or during mitochondrial isolation. We did not obtain any evidence for the existence of high molecular weight precursors of mitochondrial tRNAs. This negative result is consistent with previous in vivo transfection studies with both L. tarentolae (Lima and Simpson, RNA 1996;2:429-440) and T. brucei (Hauser and Schneider, EMBO J 1995;14:4212-4220; Schneider et al., Mol Cell Biol 1994;14:2317-2322), in which mitochondrial targeting of plasmid-expressed tRNAs was independent of the presence of 5'-flanking sequences. We conclude that the hypothesis for 5'-extended tRNA precursors in kinetoplastid mitochondrial importation remains to be verified.
Mol Biochem Parasitol 1998 May 15
PMID:Are tRNAs imported into the mitochondria of kinetoplastid protozoa as 5'-extended precursors? 966 29

Previous studies showed that components implicated in pre-rRNA processing, including U3 small nucleolar (sno)RNA, fibrillarin, nucleolin, and proteins B23 and p52, accumulate in perichromosomal regions and in numerous mitotic cytoplasmic particles, termed nucleolus-derived foci (NDF) between early anaphase and late telophase. The latter structures were analyzed for the presence of pre-rRNA by fluorescence in situ hybridization using probes for segments of pre-rRNA with known half-lives. The NDF did not contain the short-lived 5'-external transcribed spacer (ETS) leader segment upstream from the primary processing site in 47S pre-rRNA. However, the NDF contained sequences from the 5'-ETS core, 18S, internal transcribed spacer 1 (ITS1), and 28S segments and also had detectable, but significantly reduced, levels of the 3'-ETS sequence. Northern analyses showed that in mitotic cells, the latter sequences were present predominantly in 45S-46S pre-rRNAs, indicating that high-molecular weight processing intermediates are preserved during mitosis. Two additional essential processing components were also found in the NDF: U8 snoRNA and hPop1 (a protein component of RNase MRP and RNase P). Thus, the NDF appear to be large complexes containing partially processed pre-rRNA associated with processing components in which processing has been significantly suppressed. The NDF may facilitate coordinated assembly of postmitotic nucleoli.
Mol Biol Cell 1998 Sep
PMID:Partially processed pre-rRNA is preserved in association with processing components in nucleolus-derived foci during mitosis. 972 3

Phylogenetic and chemical probing data indicate that a modular RNA motif, common to loop E of eucaryotic 5 S ribosomal RNA (rRNA) and the alpha-sarcin/ricin loop of 23 S rRNA, organizes the structure of multi-helix loops in 16 S and 23 S ribosomal RNAs. The motif occurs in the 3' domain of 16 S rRNA at positions 1345-1350/1372-1376 (Escherichia coli numbering), within the three-way junction loop, which binds ribosomal protein S7, and which contains nucleotides that help to form the binding site for P-site tRNA in the ribosome. The motif also helps to structure a three-way junction within domain I of 23 S, which contains many universally conserved bases and which lies close in the primary and secondary structure to the binding site of r-protein L24. Several other highly conserved hairpin, internal, and multi-helix loops in 16 S and 23 S rRNA contain the motif, including the core junction loop of 23 S and helix 27 in the core of 16 S rRNA. Sequence conservation and range of variation in bacteria, archaea, and eucaryotes as well as chemical probing and cross-linking data, provide support for the recurrent and autonomous existence of the motif in ribosomal RNAs. Besides its presence in the hairpin ribozyme, the loop E motif is also apparent in helix P10 of bacterial RNase P, in domain P7 of one sub-group of group I introns, and in domain 3 of one subgroup of group II introns.
J Mol Biol 1998 Oct 30
PMID:A common motif organizes the structure of multi-helix loops in 16 S and 23 S ribosomal RNAs. 978 67

The function of RNase P RNA depends on its folding in space. A majority of RNase P RNAs from various bacteria show a similar secondary structure to that of Escherichia coli (M1 RNA). However, there are exceptions as exemplified by the RNase P RNA derived from the low GC-content Gram-positive bacteria Bacillus subtilis and Mycoplasma hyopneumoniae (Hyo P RNA). Previous studies using M1 RNA and Hyo P RNA suggest differences both with respect to the kinetics of cleavage as well as to cleavage site recognition. Here we have studied cleavage by these two structurally different RNase P RNAs as a function of changes in the 5' leader and the 3'-terminal CCA motif in the substrate. Our data suggest that the nucleotide at the -2 position in the 5' leader plays a role both for cleavage site recognition and for the rate of cleavage. However, depending on the identity of the -2 residue differences in the cleavage pattern comparing these two types of RNase P RNAs were observed. The results also suggest that the identity of the -1/+73 base-pair in the substrate influences the cleavage site recognition process. These findings will be related to differences in structure comparing these types of RNase P RNAs and the "RCCA-RNase P RNA" interaction. In addition, our findings will be discussed with respect to the primary structure of the tRNA genes in different bacteria.
J Mol Biol 1998 Nov 06
PMID:RNase P RNA structure and cleavage reflect the primary structure of tRNA genes. 979 Aug 39

We previously found that overexpression of arginine tRNA(CCG) from Brevibacterium albidum complements the rnpA49 mutation, which is responsible for the thermosensitivity of Escherichia coli RNase P function. In this present work, we show that the E. coli homologue tRNA also complements the same mutation, but other tRNAs do not. These results suggest that the rnpA49 mutation causes a major cellular defect in an RNase P reaction to generate the mature arginine tRNA(CCG).
Biochem Mol Biol Int 1998 Dec
PMID:Complementation of the growth defect of an rnpA49 mutant of Escherichia coli by overexpression of arginine tRNA(CCG). 989 48

The thermodynamics and folding kinetics of a circularly permuted construct of the ribozyme from Bacillus subtilis RNase P are analyzed and compared with the folding properties of the wild-type ribozyme using optical spectroscopy and catalytic activity. The folding of the wild-type ribozyme is slow due to the rearrangement of kinetically trapped species containing misfolded structures. To test whether any misfolded structure arises from interactions between the two independently folding domains of the RNase P RNA, a circular permuted form was created where one of the two phosphodiester bonds connecting these domains is broken. This construct folds approximately 15-fold faster (t1/2 approximately nine seconds) than the wild-type ribozyme at 37 degreesC. While the complete folding of both domains is kinetically indistinguishable in the wild-type ribozyme, one domain folds much faster than the other domain in the circularly permuted construct. Hence, the major kinetic trap in the folding of the wild-type RNase P RNA involves interdomain interactions. This kinetic trap is avoidable at 37 degreesC in the circularly permuted RNA. However, at temperatures below 30 degreesC or when refolding begins from an equilibrium intermediate stabilized by submillimolar concentrations of Mg2+, a subpopulation containing an interdomain misfold still forms. These results indicate that the folding pathway of this large RNA is highly malleable and can be under kinetic control.
J Mol Biol 1999 Feb 26
PMID:Pathway modulation, circular permutation and rapid RNA folding under kinetic control. 1002 46

The cyanelle of the primitive alga Cyanophora paradoxa is the only photosynthetic organelle where the ribonucleoprotein nature of ribonuclease P has been functionally proven. To increase our knowledge about RNA structure and overall composition of this enzyme, we have now determined relevant physical parameters and performed RNA accessibility experiments. Buoyant density and relative molecular mass of cyanelle RNase P were more similar to the eukaryotic (nuclear or mitochondrial) than to the bacterial enzyme type, despite the close phylogenetic relationship between plastids and cyanobacteria. Enzymatic and chemical probing was used to establish the secondary structure of cyanelle RNase P RNA. The results obtained with the naked transcript support the previously proposed, phylogenetically derived structure. Probing of the RNA in the holoenzyme resulted in reduced sensitivity at a large number of positions, indicating that these regions might be located in the interior of the ribonucleoprotein. Protection of the RNA in cyanelle RNase P was more extensive than reported for the Escherichia coli holoenzyme, but similar to the pattern observed in yeast nuclear RNase P. Taken together, these results indicate that the protein contribution in cyanelle RNase P is much larger than in the bacterial enzymes, and that the overall composition of the holoenzyme resembles that found in eukaryotes.
J Mol Biol 1999 May 28
PMID:Cyanelle RNase P: RNA structure analysis and holoenzyme properties of an organellar ribonucleoprotein enzyme. 1033 1

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