Gene/Protein
Disease
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Enzyme
Compound
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Target Concepts:
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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 have investigated the subcellular organization of the four human Y RNAs. These RNAs, which are transcribed by RNA polymerase III, are usually found complexed with the Ro autoantigen, a 60-kD protein. We designed 2'-OMe oligoribonucleotides that were complementary to accessible single-stranded regions of Y RNAs within Ro RNPs and used them in fluorescence in situ hybridization. Although all four Y RNAs were primarily cytoplasmic, oligonucleotides directed against three of the RNAs hybridized to discrete structures near the nucleolar rim. We have termed these structures "perinucleolar compartments" (PNCs). Double labeling experiments with appropriate antisera revealed that PNCs are distinct from coiled bodies and fibrillar centers. Co-hybridization with a genomic DNA clone spanning the human Y1 and Y3 genes showed that PNCs are not stably associated with the transcription site for these Y RNAs. Although 5S rDNA was often located near the nucleolar periphery, PNCs are not associated with 5S gene loci. Two additional
pol
III transcripts, the RNA components of
RNase P
and RNase MRP, did colocalize within PNCs. Most interestingly, the polypyrimidine tract-binding protein hnRNP I/PTB was also concentrated in this compartment. Possible roles for this novel nuclear subdomain in macromolecular assembly and/or nucleocytoplasmic shuttling of these five
pol
III transcripts, along with hnRNP I/PTB, are discussed.
...
PMID:A perinucleolar compartment contains several RNA polymerase III transcripts as well as the polypyrimidine tract-binding protein, hnRNP I. 753 9
In an effort to identify rapidly evolving nuclear sequences useful for phylogenetic analyses of closely related species, we isolated two genes transcribed by RNA polymerase III (
pol
III), the selenocysteine tRNA gene (TRSP) and an
RNase P
RNA (RPPH1) gene from the domestic dog (Canis familiaris). We focus on genes transcribed by
pol
III because their coding regions are small (generally 100-300 base pairs [bp]) and their essential promoter elements are located within a couple of hundred bps upstream of the coding region. Therefore, we predicted that regions flanking the coding region and outside of the promoter elements would be free of constraint and would evolve rapidly. We amplified TRSP from 23 canids and RPPH1 from 12 canids and analyzed the molecular evolution of these genes and their utility as phylogenetic markers for resolving relationships among species in Canidae. We compared the rate of evolution of the gene-flanking regions to other noncoding regions of nuclear DNA (introns) and to the mitochondrial encoded COII gene. Alignment of TRSP from 23 canids revealed that regions directly adjacent to the coding region display high sequence variability. We discuss this pattern in terms of functional mechanisms of transcription. Although the flanking regions evolve no faster than introns, both genes were found to be useful phylogenetic markers, in part, because of the synapomorphic indels found in the flanking regions. Gene trees generated from the TRSP and RPPH1 loci were generally in agreement with the published mtDNA phylogeny and are the first phylogeny of Canidae based on nuclear sequences.
...
PMID:Isolation and molecular evolution of the selenocysteine tRNA (Cf TRSP) and RNase P RNA (Cf RPPH1) genes in the dog family, Canidae. 1549 54
A regulatable promoter has been stably integrated into a human embryonic kidney cell line. The promoter is a
pol
III mouse promoter and is under the control of ponasterone A, an ecdysone inducer. The promoter controls transcription of an external guide sequence (EGS) targeted against Rpp38, a protein subunit of human
RNase P
, or of lamin A/C, a gene product located in the nucleus. The amounts of protein of both gene products are severely reduced when the EGSs are made. Several other, but not all, of the protein subunits of
RNase P
are also inhibited in both mRNA and protein levels when Rpp38 mRNA is targeted.
...
PMID:Regulated expression of functional external guide sequences in mammalian cells using a U6 RNA polymerase III promoter. 1613 90
A detailed annotation of non-protein coding RNAs is typically missing in initial releases of newly sequenced genomes. Here we report on a comprehensive ncRNA annotation of the genome of Trichoplax adhaerens, the presumably most basal metazoan whose genome has been published to-date. Since blast identified only a small fraction of the best-conserved ncRNAs--in particular rRNAs, tRNAs and some snRNAs--we developed a semi-global dynamic programming tool, GotohScan, to increase the sensitivity of the homology search. It successfully identified the full complement of major and minor spliceosomal snRNAs, the genes for
RNase P
and MRP RNAs, the SRP RNA, as well as several small nucleolar RNAs. We did not find any microRNA candidates homologous to known eumetazoan sequences. Interestingly, most ncRNAs, including the
pol
-III transcripts, appear as single-copy genes or with very small copy numbers in the Trichoplax genome.
...
PMID:Non-coding RNA annotation of the genome of Trichoplax adhaerens. 1915 Oct 82
Biogenesis of eukaryotic tRNAs requires transcription by RNA polymerase III and subsequent processing. 5' processing of precursor tRNA occurs by a single mechanism, cleavage by
RNase P
, and usually occurs before 3' processing although some conditions allow observation of the 3'-first pathway. 3' processing is relatively complex and is the focus of this review. Precursor RNA 3'-end formation begins with
pol
III termination generating a variable length 3'-oligo(U) tract that represents an underappreciated and previously unreviewed determinant of processing. Evidence that the
pol
III-intrinsic 3'exonuclease activity mediated by Rpc11p affects 3'oligo(U) length is reviewed. In addition to multiple 3' nucleases, precursor tRNA(pre-tRNA) processing involves La and Lsm, distinct oligo(U)-binding proteins with proposed chaperone activities. 3' processing is performed by the endonuclease RNase Z or the exonuclease Rex1p (possibly others) along alternate pathways conditional on La. We review a Schizosaccharomyces pombe tRNA reporter system that has been used to distinguish two chaperone activities of La protein to its two conserved RNA binding motifs. Pre-tRNAs with structural impairments are degraded by a nuclear surveillance system that mediates polyadenylation by the TRAMP complex followed by 3'-digestion by the nuclear exosome which appears to compete with 3' processing. We also try to reconcile limited data on pre-tRNA processing and Lsm proteins which largely affect precursors but not mature tRNAs.A pathway is proposed in which 3' oligo(U) length is a primary determinant of La binding with subsequent steps distinguished by 3'-endo versus exo nucleases,chaperone activities, and nuclear surveillance.
...
PMID:3' processing of eukaryotic precursor tRNAs. 2157 61
Ribonuclease P (
RNase P
) is an essential enzyme required for 5'-maturation of tRNA. While an RNA-free, protein-based form of
RNase P
exists in eukaryotes, the ribonucleoprotein (RNP) form is found in all domains of life. The catalytic component of the RNP is an RNA known as
RNase P
RNA (RPR). Eukaryotic RPR genes are typically transcribed by RNA polymerase III (
pol
III). Here we showed that the RPR gene in Drosophila, which is annotated in the intron of a
pol
II-transcribed protein-coding gene, lacks signals for transcription by
pol
III. Using reporter gene constructs that include the RPR-coding intron from Drosophila, we found that the intron contains all the sequences necessary for production of mature RPR but is dependent on the promoter of the recipient gene for expression. We also demonstrated that the intron-coded RPR copurifies with
RNase P
and is required for its activity. Analysis of RPR genes in various animal genomes revealed a striking divide in the animal kingdom that separates insects and crustaceans into a single group in which RPR genes lack signals for independent transcription and are embedded in different protein-coding genes. Our findings provide evidence for a genetic event that occurred approximately 500 million years ago in the arthropod lineage, which switched the control of the transcription of RPR from
pol
III to
pol
II.
...
PMID:Transcriptional control of an essential ribozyme in Drosophila reveals an ancient evolutionary divide in animals. 2556 72
