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Query: EC:2.7.7.6 (RNA polymerase)
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RNA transcribed from genomic Xenopus laevis DNA by RNA polymerase III in HeLa-cell extract was found in discrete size classes and was transcribed from at least two different Xenopus repeat DNA species. Very little 5S ribosomal RNA was transcribed, contrasting with results obtained on transcription of genomic Xenopus DNA by Xenopus extract [Bogenhagen et al. (1982) Cell 28, 413-421]. The low transcription was not due to an inability to use 5S rDNA templates, since the cloned Xenopus 5S ribosomal gene and pseudogene were effective templates for RNA polymerase III in HeLa extract. RNA transcribed from genomic bovine DNA by RNA polymerase III in HeLa-cell cytosol extract consisted of 120-nucleotide RNA and a larger amount of heterogeneously sized RNA (180-650 nucleotides). Only a small portion of the 120-nucleotide RNA was 5S rRNA. Most of the 120-nucleotide RNA and the larger RNA species were transcribed from one bovine repeat DNA. Genes for 5S rRNA and bovine repeat DNA were transcribed roughly in proportion to their frequency in Bos, contrasting with results in a homologous system in which transcription of repeat genes is repressed [Furth (1985) Biochem. Biophys. Res. Commun. 131, 551-556]. Bovine 5S rRNA genes appear to be concentrated on one DNA fragment obtained by restriction-enzyme-HindIII digestion of genomic bovine DNA.
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PMID:Transcription of genomic bovine and Xenopus laevis DNA species by RNA polymerase III in HeLa-cell cytosol extracts. 380 Sep 21

The processed pseudogenes reported to date fall into three categories: those that are a complete copy of the mRNA transcribed from the functional gene, those that are only a partial copy of the corresponding mRNA, and those that contain sequences in addition to those expected to be present in the mRNA. The general structural characteristics of these processed pseudogenes include the complete lack of intervening sequences found in the functional counterparts, a poly A tract at the 3' end, and direct repeats flanking the pseudogene sequence. In all the cases studied, these pseudogenes have been found to be on a different chromosome from their functional counterpart. These characteristics have led investigators to suggest that an RNA intermediate, in many cases the mRNA of the functional gene, is involved in the production of these pseudogenes. The mechanism by which processed pseudogenes arose involves the integration of the mRNA, or its cDNA copy, into a staggered chromosome break, followed by DNA synthesis and repair. I suggest that all the transcripts that gave rise to these pseudogenes were actually produced in the germ line cell. The transcripts that gave rise to the processed pseudogenes that are direct copies of the corresponding mRNA resulted from RNA polymerase II transcription of the functional counterpart. Pseudogenes that are not a direct copy of the corresponding mRNA may have resulted from RNA polymerase III transcription. If this is indeed the case, one need not postulate the involvement of retroviruses to explain the presence of processed pseudogenes corresponding to genes that are not expressed in the germ line. Following the integration event, processed pseudogenes can no longer be transcribed to produce the functional mRNA from which they arose. This inability to be transcribed by RNA polymerase II is not surprising considering that processed pseudogenes seem to be randomly integrated into the genome. Therefore, integration of a processed pseudogene such that RNA polymerase II transcriptional promoters are correctly positioned 5' to the resultant pseudogene is an unlikely event. The presence of processed pseudogenes seems peculiar to mammals. In fact, evolutionary studies indicate that processed pseudogenes are of relatively recent origin. In fact, at least one processed pseudogene, the human DHFR psi 1, has been formed so recently that it is polymorphic.
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PMID:Processed pseudogenes: characteristics and evolution. 390 43

The sequence of the DNA between two pseudogenes in the human alpha-like globin gene cluster has been determined. Comparison of this sequence with sequences from other alpha-like globin gene clusters revealed another pseudogene, psi alpha 2, between the previously recognized pseudogenes zeta 1 and psi alpha 1. Therefore, the human alpha-like globin gene family is organized 5'-zeta 2-zeta 1-psi alpha 2-psi alpha 1-alpha 2-alpha 1-3'. The new pseudogene psi alpha 2 is very close to zeta 1, beginning only 65 base pairs 3' to the polyadenylation site of zeta 1. The first exon and the first intron of psi alpha 2 are interrupted by large inserts which are flanked by short (6 to 8 base pairs) direct repeats. The pseudogene psi alpha 2 lacks a promoter for transcription by RNA polymerase II, the first exon is highly divergent, one splice site is mutated, and five different frameshift mutations have occurred in the coding regions. Thus psi alpha 2 cannot encode a globin polypeptide. This pseudogene was not recognized in previous hybridization analyses of the human alpha-like globin gene cluster, and our discovery of it by sequence analysis suggests that divergent copies of a large number of genes may comprise a substantial fraction of the slowly renaturing DNA of mammalian genomes.
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PMID:A previously undetected pseudogene in the human alpha globin gene cluster. 395 1

A genomic DNA fragment from Dictyostelium discoideum was characterized. This DNA, although 74% d(A + T)-rich, codes for a putative tRNAValGUU. The tRNAVal gene overlaps at its 5' half with another RNA polymerase III transcription unit. This RNA polymerase III transcription unit can be folded into a tRNA-like shape and is comprised of significant amounts of invariant and semi-invariant nucleotides present in all eukaryotic tRNAs. This unit contains the two promoter blocks defined for RNA polymerase III, which are homologous to recently defined promoter elements to the extent of 76-88% (A block) and 86-93% (B block) respectively [Sharp et al. (1981) Proc. Natl Acad. Sci. USA 78, 6657-6661]. Both of the overlapping class III genes are transcribed in germinal vesicle extracts prepared from Xenopus laevis oocytes as a single transcription unit, resulting in an unusually large product compared to primary transcripts of other tRNA genes. The unit is not transcribed in HeLa extracts but it competes very strongly for transcription factor(s) under the conditions of stable transcription complex formation. Although the whole unit is transcribed, it is believed that only one functional product is formed. Therefore we define the tRNA-like structure, coded for on this class III transcription unit, as a putative tRNA 'pseudogene' meaning that, although it is transcribed by RNA polymerase III, it is not likely to mature to a functional tRNA.
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PMID:Characterisation of a Dictyostelium discoideum DNA fragment coding for a putative tRNAValGUU gene. Evidence for a single transcription unit consisting of two overlapping class III genes. 396 66

DNA that encodes the Xenopus laevis 5S pseudogene is transcribed following microinjection into oocyte nuclei. Transcription in injected oocytes is accurate, is mediated by RNA polymerase III and is initiated at the first nucleotide of the pseudogene. The level of pseudogene transcription can be as high as 85% of that of the normal 5S gene. The results suggest that the observed absence of pseudogene transcripts of defined length in vivo probably is due to inefficient termination of transcription.
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PMID:A transcriptionally active pseudogene in xenopus laevis oocyte 5S DNA. 616 89

We have isolated four clones which hybridize with U6 (4.8S) nuclear RNA, a mammalian small nuclear RNA(nRNA), from DNA of BALB/C mouse liver. Their restriction maps are totally different from each other, indicating that they derived from different loci in the mouse genome. The nucleotide sequences around the hybridizing region in the three clones have been determined. One clone gives a gene that is co-linear with the U6 RNA. There is a sequence TATAAAT beginning 31 nucleotides upstream of the gene, which may suggest that the U6 RNA is transcribed by RNA polymerase II. The other two clones contain a pseudogene for the U6 RNA which has 7 or 9 nucleotide changes from the RNA. The pseudogenes are surrounded by radically different sequences from those surrounding the gene, and they are closely linked to a pseudogene for another snRNA, 4.5S-I RNA, or a part of highly repetitive an interspersed sequence B1.
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PMID:Nucleotide sequences of mouse genomic loci including a gene or pseudogene for U6 (4.8S) nuclear RNA. 617 74

We previously demonstrated that pseudogenes complementary to the small nuclear RNAs U1, U2 and U3 are dispersed and abundant in the human genome. Here we report that three pseudogenes (U1.101, U2.13 and U3.5) are flanked by perfect short direct repeats of 16 to 19 base pairs. In all three pseudogenes. the upstream direct repeat abuts a DNA sequence corresponding to the 5' end of the mature snRNA; in U2.13 and U3.5, the downstream direct repeat immediately follows the truncated 3' end of the snRNA sequence, whereas in U1.101, the downstream direct repeat is separated from the 3, end of the full-length snRNA sequence by a short A-rich region. We consider the direct repeats to be an indication that these three pseudogenes were created by insertion of snRNA information into a new chromosomal locus. To explain why the upstream repeat abuts a DNA sequence complementary to the 5' end of the mature snRNA, we propose a model for insertion that uses a reverse transcript of the snRNA as an intermediate. Furthermore, we note similarities between the structure of all three pseudogene loci and the Alu family of middle repetitive DNA sequences. These similarities suggest that some Alu family sequences are mobile genetic elements that can transpose to new chromosomal loci using as an intermediate a cDNA copy of an RNA transcribed from the Alu family element by RNA polymerase III.
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PMID:Direct repeats flank three small nuclear RNA pseudogenes in the human genome. 617 30

We have isolated four segments of Drosophila melanogaster DNA that hybridize to homologous initiator tRNAMet. Three of the cloned fragments contain initiator tRNA genes, each of which can be transcribed in vitro. The fourth clone, pPW568, contains an initiator tRNA pseudogene which is not transcribed in vitro by RNA polymerase III. The pseudogene is contained in a 1.15 kb DNA fragment. This fragment has the characteristics of dispersed repetitive DNA and hybridizes in situ to at least 30 sites in the Drosophila genome. The arrangement of the initiator tRNA genes we have isolated, is different to that of other Drosophila tRNA gene families. The initiator tRNA genes are not clustered nor intermingled with other tRNA genes. They occur as single copies within an approximately 415-bp repeat segment, which is separated from other initiator tRNA genes by a mean distance of 17 kb. In situ hybridization to polytene chromosomes localizes these genes to the 61D region of the Drosophila genome. Hybridization analysis of genomic DNA indicates the presence of 8-9 non-allelic initiator tRNA genes in Drosophila melanogaster.
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PMID:The initiator tRNA genes of Drosophila melanogaster: evidence for a tRNA pseudogene. 627 11

A minor class of introns with noncanonical splice sites has been identified in both vertebrate and invertebrate genomes. The divergent consensus sequences within these introns suggest that splicing might be via a mechanism distinct from that used by the major class of introns. The low abundance U12 snRNA has been proposed to base pair with the predicted branch site sequence of these minor class introns, probably bulging out an adenosine to act as the nucleophile in the first step of splicing. We have identified homologues of the previously characterized human U12 snRNA in both mouse and chicken, where the minor class of introns has also been found. The U12 sequences that potentially base pair with the putative branch site are invariant. Additional conserved sequences at the 5' end of U12 snRNA could dynamically base pair with U6 snRNA sequences flanking the hexanucleotide ACAGAG to form structures analogous to those of three U2-U6 interactions genetically defined as important in the major class of spliceosome. We have also isolated two human U12 snRNA genes. One gene is functional for transcription of U12 snRNA, whereas the other appears to be a pseudogene. Sequences of the 3' box in both U12 snRNA genes are strikingly similar and bear high resemblance to those of U1 and U2 genes. Upstream elements, including the PSE and the DSE, have been identified and characterized in the functional gene. These features indicate that transcription of U12 snRNA is driven by RNA polymerase II.
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PMID:U12 snRNA in vertebrates: evolutionary conservation of 5' sequences implicated in splicing of pre-mRNAs containing a minor class of introns. 748 23

The generation of infectious rabies virus (RV), a non-segmented negative-stranded RNA virus of the Rhabdoviridae family, entirely from cloned cDNA is described. Simultaneous intracellular expression of genetically marked full-length RV antigenome-like T7 RNA polymerase transcripts and RV N, P and L proteins from transfected plasmids resulted in formation of transcriptionally active nucleocapsids and subsequent assembly and budding of infectious rabies virions. In addition to authentic RV, two novel infectious RVs characterized by predicted transcription patterns were recovered from modified cDNA. Deletion of the entire non-translated pseudogene region, which is conserved in all naturally occurring RVs, did not impair propagation of the resulting virus in cell culture. This indicates that non-essential genetic material might be present in the genomes of non-segmented RNA viruses. The introduction of a functional extra cistron border into the genome of another virus resulted in the transcription of an additional polyadenylated mRNA containing pseudogene sequences. The possibility of manipulating the RV genome by recombinant DNA techniques using the described procedure--potentially applicable also for other negative-stranded viruses--greatly facilitates the investigation of RV genetics, virus-host interactions and rabies pathogenesis and provides a tool for the design of new generations of live vaccines.
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PMID:Infectious rabies viruses from cloned cDNA. 792 65

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