EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A bacteriophage gamma Ch4A clone containing a 22-kb rat DNA insert was isolated and found to contain a solitary tRNA(Phe)GAA gene and, 436 bp downstream of it, an Alu-like element. The nucleotide sequence of a 1141-bp DNA fragment containing these genes was determined. The rat tRNA(Phe)GAA gene, with the exception of an additional A in the extra arm, has a sequence identical to that of a rabbit liver tRNA(Phe). The Alu-like element belongs to the rodent B2 family of short interspersed repetitive nucleotide sequences. This repetitive element, B2Phe, is flanked by 12-bp direct repeats, contains an internal split promoter (block A and block B) for RNA polymerase III and is devoid of an A-rich segment at the 3' end. Like other members of the B2 family, the B2Phe element presents 64% sequence homology with rat serine tRNA and contains a serine (GCT) anticodon. Both tRNA(Phe)GAA gene and B2Phe element were found to be transcriptionally active in HeLa cell and Xenopus oocyte nuclear extracts. The tRNA(Phe) gene transcripts were processed during the course of transcription to form mature-size tRNA(Phe). The transcription efficiency of the B2Phe element was found to be an order of magnitude higher than that of the tRNA(Phe) gene. Competition experiments demonstrate that the B2Phe DNA can form a more stable transcription complex than the tRNA(Phe) gene and compete with it for binding of transcription factors.
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PMID:Nucleotide sequence and transcription of a rat tRNA(Phe) gene and a neighboring Alu-like element. 323 68

The elongation rate of RNAs synthesized from AI promoters of T7 phage DNA and its deletion mutant delta DIII T7 DNA by E. coli RNA polymerase was analyzed. The distribution of incorporation rates of any definite nucleotides at any definite position along the two RNA chains was studied. The minimal structure which reproducibly forms pauses seems to be trinucleotide. Two main groups of trinucleotides could be distinguished: 1) those mostly associated with pauses and; 2) those usually found in pause free regions. The first group consists of AUG, AUA, AUC, AAU, GUG, GUA, CGU, CGC, UUA, UUU; the second one comprises AAA, CAA, CCC, UCC, CUA, CUG, CUC, GGG, ACU, GAG, GAA, GGA. A model accounting for intermittent elongation has been developed. It is based on the hypothesis that the kinetic constants of each nucleotide incorporation to and pyrophosphorolysis from the 3'-end of the growing RNA chain depend on the nature of the incoming nucleotide as well as on the nature of a nucleotide residue situated at the 3'-end of the growing RNA. A general equation describing the pause distribution along the RNA of a known nucleotide sequence is proposed.
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PMID:[Effect of the primary structure of RNA on the pulse character of RNA elongation in vitro by Escherichia coli RNA polymerase: a model]. 616 4

An unusual S1-nuclease sensitive microsatellite (STMS) has been found in the single copy, rat polymeric immunoglobulin receptor gene (PIGR) terminal exon. In Fisher rats, elements within or beyond the STMS are expressed variably in the 3' untranslated regions (3'UTRs) of two 'Groups' of PIGR-encoded hepatic mRNAs (pIg-R) during liver regeneration. STMS elements include neighboring constant regions (a 60-bp d[GA]-rich tract with a chi-like octamer, followed by 15 tandem d[GGA] repeats) that merge directly with 36 or 39 tandem d[GAA] repeats (Fisher or Wistar strains, respectively) interrupted by d[AA] between their 5th-6th repeat units. The Wistar STMS is flanked upstream by two regions of nearly contiguous d[CA] or d[CT] repeats in the 3' end of intron 8; and downstream, by a 283 bp 'unit' containing several inversions at its 5' end, and two polyadenylation signals at its 3' end. The 283 nt unit is expressed in Group 1 pIg-R mRNAs; but it is absent in the Group 2 family so that their GAA repeats merge with their poly A tails. In contrast to genomic sequence, GGA triplet repeats are amplified (n > or = 24-26), whereas GAA triplet repeats are truncated variably (n < or = 9-37) and expressed uninterruptedly in both mRNA Groups. These results suggest that 3' end processing of the rat PIGR gene may involve misalignment, slippage and premature termination of RNA polymerase II. The function of this unusual processing and possible roles of chi-like octamers in quiescent or extrahepatic tissues are discussed.
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PMID:Discordant expression and variable numbers of neighboring GGA- and GAA-rich triplet repeats in the 3' untranslated regions of two groups of messenger RNAs encoded by the rat polymeric immunoglobulin receptor gene. 773 89

A study of the recognition of tRNA(Cys) by Escherichia coli cysteinyl-tRNA synthetase using in vivo and in vitro methods was performed. All three anticodon nucleotides, the discriminator nucleotide (73), and some elements within the tertiary domain (the D stem/loop, the T psi C stem/loop, and the variable loop) are important for recognition; the anticodon stem and acceptor stem appear to contain no essential elements. A T7 RNA polymerase transcript corresponding to tRNA(Cys) is only a 5.5-fold worse substrate than native tRNA(Cys) (in terms of the specificity constant, kcat/Km), mainly due to an increase in the value of Km for the transcript. The greatest loss of specificity caused by mutation of a single nucleotide occurs when the discriminator U73 is changed; kcat/Km declines 3-4 orders of magnitude depending on the substitution. Mutations in the wobble nucleotide of the anticodon also cause reductions in the specificity constant of 3 orders of magnitude, while mutations in the other anticodon nucleotides caused lesser effects. Interestingly, a C35A mutation (with the phenylalanine anticodon GAA) had no effect on aminoacylation by the cysteinyl-tRNA synthetase. Several amber suppressor tRNAs were constructed whose in vivo identity did not correlate with their in vitro specificity, indicating the need for both types of experiments to understand the factors which maintain tRNA specificity.
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PMID:Recognition of tRNA(Cys) by Escherichia coli cysteinyl-tRNA synthetase. 833 41

We examined the MLL genomic translocation breakpoint in acute myeloid leukemia of infant twins. Southern blot analysis in both cases showed two identical MLL gene rearrangements indicating chromosomal translocation. The rearrangements were detectable in the second twin before signs of clinical disease and the intensity relative to the normal fragment indicated that the translocation was not constitutional. Fluorescence in situ hybridization with an MLL-specific probe and karyotype analyses suggested t(11;22)(q23;q11. 2) disrupting MLL. Known 5' sequence from MLL but unknown 3' sequence from chromosome band 22q11.2 formed the breakpoint junction on the der(11) chromosome. We used panhandle variant PCR to clone the translocation breakpoint. By ligating a single-stranded oligonucleotide that was homologous to known 5' MLL genomic sequence to the 5' ends of BamHI-digested DNA through a bridging oligonucleotide, we formed the stem-loop template for panhandle variant PCR which yielded products of 3.9 kb. The MLL genomic breakpoint was in intron 7. The sequence of the partner DNA from band 22q11.2 was identical to the hCDCrel (human cell division cycle related) gene that maps to the region commonly deleted in DiGeorge and velocardiofacial syndromes. Both MLL and hCDCrel contained homologous CT, TTTGTG, and GAA sequences within a few base pairs of their respective breakpoints, which may have been important in uniting these two genes by translocation. Reverse transcriptase-PCR amplified an in-frame fusion of MLL exon 7 to hCDCrel exon 3, indicating that an MLL-hCDCrel chimeric mRNA had been transcribed. Panhandle variant PCR is a powerful strategy for cloning translocation breakpoints where the partner gene is undetermined. This application of the method identified a region of chromosome band 22q11.2 involved in both leukemia and a constitutional disorder.
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PMID:t(11;22)(q23;q11.2) In acute myeloid leukemia of infant twins fuses MLL with hCDCrel, a cell division cycle gene in the genomic region of deletion in DiGeorge and velocardiofacial syndromes. 960 Sep 80

Large expansions of the trinucleotide repeat GAA*TTC within the first intron of the X25 (frataxin) gene cause Friedreich's ataxia, the most common inherited ataxia. Expansion leads to reduced levels of frataxin mRNA in affected individuals. Here we show that GAA*TTC tracts, in the absence of any other frataxin gene sequences, can reduce the amount of GAA-containing transcript produced in a defined in vitro transcription system. This effect is due to an impediment to elongation that forms in the GAA*TTC tract during transcription, a phenomenon that is exacerbated by both superhelical stress and increased tract length. On supercoiled templates the major truncations of the GAA-containing transcripts occur in the distal (3') end of the GAA repeat. To account for these observations we present a model in which an RNA polymerase advancing within a long GAA*TTC tract initiates the transient formation of an R*R*Y intramolecular DNA triplex. The non-template (GAA) strand folds back creating a loop in the template strand, and the polymerase is paused at the distal triplex-duplex junction.
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PMID:The GAA*TTC triplet repeat expanded in Friedreich's ataxia impedes transcription elongation by T7 RNA polymerase in a length and supercoil dependent manner. 1090 40

Expanded GAA.TTC trinucleotide repeats in intron 1 of the frataxin gene cause Friedreich's ataxia (FRDA) by reducing frataxin mRNA levels. Insufficient frataxin, a nuclear encoded mitochondrial protein, leads to the progressive neurodegeneration and cardiomyopathy characteristic of FRDA. Previously we demonstrated that long GAA.TTC tracts impede transcription elongation in vitro and provided evidence that the impediment results from an intramolecular purine.purine.pyrimidine DNA triplex formed behind an advancing RNA polymerase. Our model predicts that inhibiting formation of this triplex during transcription will increase successful elongation through GAA.TTC tracts. Here we show that this is the case. Oligodeoxyribonucleotides designed to block particular types of triplex formation provide specific and concentration-dependent increases in full-length transcript. In principle, therapeutic agents that selectively interfere with triplex formation could alleviate the frataxin transcript insufficiency caused by pathogenic FRDA alleles.
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PMID:Alleviating transcript insufficiency caused by Friedreich's ataxia triplet repeats. 1112 84

Friedreich's ataxia (FRDA) is an autosomal recessive neurodegenerative disease caused by the expansion of GAA.TTC repeats in the first intron of the frataxin (X25) gene. FRDA patients carrying two expanded GAA.TTC repeats show very low levels of mature frataxin mRNA and protein. A novel type of unusual DNA structure, sticky DNA, was previously found in the expanded GAA.TTC repeats from FRDA patients. To evaluate the effect of sticky DNA on transcription, in vitro transcription studies of (GAA.TTC)(n) repeats (where n = 9-150) were carried out using T7 or SP6 RNA polymerase. When a gel-isolated sticky DNA template was transcribed, the amount of full-length RNA synthesized was significantly reduced compared with the transcription of the linear template. Surprisingly, transcriptional inhibition was observed not only for the sticky DNA template but also another DNA molecule used as an internal control in an orientation-independent manner. The molecular mechanism of transcriptional inhibition by sticky DNA was a sequestration of the RNA polymerases by direct binding to the complex DNA structure. Moreover, plasmids containing the (GAAGGA.TCCTTC)(65) repeat, which does not form sticky DNA, did not inhibit in vitro transcription, as expected. These results suggest that the role of sticky DNA in FRDA may be the sequestration of transcription factors.
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PMID:Sticky DNA, a self-associated complex formed at long GAA*TTC repeats in intron 1 of the frataxin gene, inhibits transcription. 1134 71

In order to clone candidate tumor suppressor genes whose loss contributes to the pathogenesis of neuroblastoma (NB), we performed polymerase chain reaction (PCR) screening using a high-density sequence tagged site-content map within a commonly deleted region (chromosome band 1p36) in 24 NB cell lines. We found a approximately 480 kb homozygously deleted region at chromosome band 1p36.2 in one of the 24 NB cell lines, NB-1, and cloned the human homologue (KIF1B-beta) of the mouseKif1B-beta gene in this region. The KIF1B-beta gene had at least 47 exons, all of which had a classic exon-intron boundary structure. Mouse Kif1B is a microtubule-based putative anterograde motor protein for the transport of mitochondria in neural cells. We performed mutational analysis of the KIF1B-beta gene in 23 cell lines using 46 sets of primers and also an allelic imbalance (AI) analysis of KIF1B-beta in 50 fresh NB samples. A missense mutation at codon 1554, GTG (Gly) to ATG (Met), silent mutations at codon 409 (ACG to ACA) and codon 1721 (ACC to ACT), and polymorphisms at codon 170, GAT (Asp) to GAA (Glu), and at codon 1087, TAT (Tyr), to TGT (Cys), were all identified, although their functional significances remain to be determined. The AI for KIF1B-beta was slightly higher (38%) than those for the other two markers (D1S244, D1S1350) (35 and 32%) within the commonly deleted region (1p36). Reverse transcriptase-PCR analysis of the KIF1B-beta gene revealed obvious expression in all NB cell lines except NB-1, although decreased expression of the KIF1B-beta gene was found in a subset of early- and advanced-stage NBs. These results suggest that the KIF1B-beta gene may not be a candidate for tumor suppressor gene of NB.
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PMID:Genomic structure and mutational analysis of the human KIF1B gene which is homozygously deleted in neuroblastoma at chromosome 1p36.2. 1152 94

DNA repeat expansion is the genetic basis for a growing number of neurological disorders. While the largest subset of these diseases results in an increase in the length of a polyglutamine tract in the protein encoded by the affected gene, the most common form of inherited mental retardation, fragile X syndrome, and the most common inherited ataxia, Friedreich's ataxia, are both caused by expansions that are transcribed but not translated. These expansions both decrease expression of the gene in which the expanded repeat is located, but they do so by quite different mechanisms. In fragile X syndrome, CGG. CCG expansion in the 5' untranslated region of the FMR1 gene leads to hypermethylation of the repeats and the adjacent CpG-rich promoter. Methylation prevents the binding of the transcription factor alpha-Pal/NRF-1, and may indirectly affect the binding of other factors via the formation of transcriptionally silent chromatin. In Friedreich's ataxia, GAA. TTC expansion in an intron of the FRDA gene reduces expression by interfering with transcription elongation. The model that best describes the available data is transcription-driven formation of a transient purine. purine. pyrimidine DNA triplex behind an advancing RNA polymerase. This structure lassoes the RNA polymerase that caused it, trapping the enzyme on the template.
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PMID:Fragile X syndrome and Friedreich's ataxia: two different paradigms for repeat induced transcript insufficiency. 1171 74

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