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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)

DNA sequence analysis of RpII215, the gene that encodes the Mr215,000 subunit of RNA polymerase II (EC 2.7.7.6) in Drosophila melanogaster, reveals that the 3'-terminal exon includes a region encoding a C-terminal domain composed of 42 repeats of a seven-residue amino acid consensus sequence, Tyr-Ser-Pro-Thr-Ser-Pro-Ser. A hemi- and homozygous lethal P-element insertion into the coding sequence of this domain causes premature translation termination and therefore truncation of the protein, leaving only 20 heptamer repeats. While loss of approximately 50% of the repeat structure in this mutant is a lethal event in vivo, enzyme containing the truncated subunit remains capable of accurate initiation at promoters in vitro. Moreover, treatment of purified intact RNA polymerase II with protease, to remove the entire repeat domain, does not eliminate the enzyme's ability to initiate accurately in vitro. Possible in vivo functions for this unusual protein domain are considered in light of these results.
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PMID:The C-terminal repeat domain of RNA polymerase II largest subunit is essential in vivo but is not required for accurate transcription initiation in vitro. 313 61

The carboxyl-terminal domain (CTD) of the mouse RNA polymerase II largest subunit consists of 52 repeats of a seven-amino-acid block with the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. A genetic approach was used to determine whether the CTD plays an essential role in RNA polymerase function. Deletion, insertion, and substitution mutations were created in the repetitive region of an alpha-amanitin-resistant largest-subunit gene. The effects of these mutations on RNA polymerase II activity were assayed by measuring the ability of mutant genes to confer alpha-amanitin resistance after transfection of susceptible rodent cells. Mutations that resulted in CTDs containing between 36 and 78 repeats had no effect on the transfer of alpha-amanitin resistance, whereas mutations with 25 or fewer repeats were inactive in this assay. Mutations that contained 29, 31, or 32 repeats had an intermediate effect; the number of alpha-amanitin-resistant colonies was lower and the colonies obtained were smaller, indicating that the mutant RNA polymerase II was defective. In addition, not all of the heptameric repeats were functionally equivalent in that repeats that diverged in up to three amino acids from the consensus sequence could not substitute for the conserved heptamer repeats. We concluded that the CTD is essential for RNA polymerase II activity, since substantial mutations in this region result in loss of function.
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PMID:Genetic analysis of the repetitive carboxyl-terminal domain of the largest subunit of mouse RNA polymerase II. 327 73

The primary structure of all actins except that isolated from Naegleria gruberi contains a unique N tau-methylhistidine (MeHis) at position 73. This modified residue has been implicated as possibly being important for the post-translational processing of actin's amino terminus, the binding of actin to DNase I, and in the polymerization of G-actin. We have investigated the potential role of MeHis in each of these processes by utilizing site-directed mutagenesis to change His-73 of skeletal muscle actin to Arg and Tyr. Wild type and mutant actins were synthesized in vivo, using non-muscle cells transfected with mutant cDNAs, and in vitro by translating mutant RNAs synthesized using SP6 RNA polymerase in a rabbit reticulocyte lysate. We have found that actins containing Arg or Tyr at position 73 undergo amino-terminal processing, bind to DNase I-agarose, and become incorporated into the cytoskeleton of a nonmuscle cell as efficiently as wild type actin. Furthermore, using an in vitro copolymerization assay we have found that although there is no difference between the Arg mutant and the wild type actins, the Tyr mutant has a slightly greater critical concentration for polymerization. These results show that MeHis is not absolutely required for any of these processes.
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PMID:Studies on the role of actin's N tau-methylhistidine using oligodeoxynucleotide-directed site-specific mutagenesis. 330 54

The RNA polymerase II large subunit contains tandem copies of the sequence Pro Thr Ser Pro Ser Tyr Ser at its carboxyl terminus, the number of which varies from 26 in yeast to 52 in mice. Our results indicate that the heptapeptide repeat sequence is unique and essential to RNA polymerase II. We have determined that a portion of the heptapeptide repeat domain is essential for viability by constructing and analyzing unidirectional deletions of the carboxy-terminal coding sequence in yeast. Cells containing an RNA polymerase II large subunit with less than 10 complete heptapeptide repeats are inviable, those containing 10-12 complete repeats are conditionally viable, and those with 13 or more complete repeats are unconditionally viable. The inviable deletion mutants studied here have truncated RNA polymerase subunits that are stable, but functionally deficient. Finally, the number of repeat units is polymorphic in wild-type yeast strains. These results have implications for the function of this unusual sequence in transcription.
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PMID:Functional redundancy and structural polymorphism in the large subunit of RNA polymerase II. 330 59

The ogr gene product of bacteriophage P2 is a positive regulatory factor required for P2 late-gene transcription. We have determined the nucleotide sequence of the ogr gene, which encodes a basic polypeptide of 72 amino acids. P2 growth is blocked by a host mutation, rpoA109, in the alpha subunit of DNA-dependent RNA polymerase. The ogr52 mutation, which allows P2 to grow in an rpoA109 strain, was shown to be a single nucleotide change, in the codon for residue 42, that changes tyrosine to cysteine. The predicted amino acid sequence of the Ogr protein does not show similarity to DNA-binding proteins that are known to affect promoter recognition, to sigma factors, or to other characterized transcriptional regulatory proteins. We have inserted the ogr gene into a plasmid under control of the leftward promoter and operator of bacteriophage lambda. Thermal induction of ogr gene expression in this plasmid results in overproduction of a small protein that has been shown by complementation to possess Ogr function.
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PMID:Regulation of bacteriophage P2 late-gene expression: the ogr gene. 345 77

The effects of guanosine tetraphosphate (ppGpp) and guanosine pentaphosphate (pppGpp), both produced by E. coli, were measured on the activities of several genes in a cell-free system. Gene activity is measured as gene-directed synthesis of biochemically competent protein or transfer RNA. Both ppGpp and pppGpp stimulated the activities of the ara, lac, and trp operons and inhibited the arg operon. Production of transfer-RNA(Tyr) was unaffected by moderate levels of either ppGpp or pppGpp and only slightly inhibited at higher levels of ppGpp. Since the cell-free reaction mixtures hydrolyze pppGpp to ppGpp, we performed similar studies with a hydrolysis-resistant analog of pppGpp, the beta-gamma methylenyl derivative (pcppGpp). In general, pcppGpp shows the same inhibitory potency as pppGpp for the arg operon, but lacks the stimulatory effects on the ara, lac, and trp operons. This result suggests that the stimulation of these gene activities is specific for ppGpp.Under similar conditions, pppGpp and ppGpp show a slight inhibitory effect on the messenger-directed synthesis of beta-galactosidase and no effect on the messenger-directed synthesis of MS2 viral-coat protein. These observations, together with the fact that in the same system these nucleotides affect coupled transcription and translation, lead us to surmise that the activities of pppGpp and ppGpp are exerted at the level of RNA polymerase activity.
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PMID:Effects of guanosine tetraphosphate, guanosine pentaphosphate, and beta-gamma methylenyl-guanosine pentaphosphate on gene expression of Escherichia coli in vitro. 435 31

Using a simple three-step procedure, we have isolated thermosensitive mutants of E. coli that are specifically defective in transfer RNA (tRNA) synthesis. Our procedure was designed to identify mutants that are unable to make su(3) (+) tRNA(Tyr) or grow at the restrictive temperature, yet under the same conditions they retain the ability to make mRNA and protein. The mutants obtained have been analyzed, and they are defective in different steps in the synthesis of functional tRNA at the restrictive temperature. Some of them may fail to modify certain bases in the tRNA. Two mutants are unable to process the 5' end of tRNA precursor molecules. Three are unable to cleave precursor molecules at the 3' end. 11 Mutants can not synthesize any tRNA molecules or tRNA precursors. We speculate that these latter mutants may be defective in RNA polymerase or in an RNA polymerase factor specific for stable RNA synthesis.
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PMID:Mutants of Escherichia coli thermosensitive for the synthesis of transfer RNA. 457 13

1. The perturbing effect of glycerol on the direct spectrum of Escherichia coli DNA-dependent RNA polymerase has been studied. 2. By comparison with model compounds and with the unfolded polymerase in 3.8m-urea it was possible to determine the ratio of tyrosine and tryptophan residues present. On reduction of the urea-treated enzyme with 2-mercaptoethanol, no further change in the difference spectrum occurred. 3. The amino acid composition of the enzyme is given. 4. In the intact protein approx. 30% of the tryptophan and 54% of the tyrosine residues were exposed. In conjunction with the extinction value and molecular weight this corresponded to 7 tryptophan residues and 57 tyrosine residues on the surface and 16 tryptophan residues and 48 tyrosine residues ;buried'. 5. The optical rotatory dispersion of the enzyme was unaffected by 20% glycerol. 6. The helix content calculated from Moffit plots over 560-300nm was 13%, and from the 233nm trough 13%.
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PMID:Location of aromatic amino acids and belix content in Escherichia coli ribonucleic acid polymerase. 494 33

The DNA sequence of a cluster of twenty-one tRNA genes distal to a rRNA gene set in B. subtilis was determined. None of the tRNA genes are repeated in the sequence. The only classes of tRNAs that are not represented are those for cysteine, glutamine, tryptophan, and tyrosine. Three of the tRNA genes in this cluster do not have the 3'-CCA sequence encoded in the gene. There is no RNA polymerase terminator sequence in the region between the 5S gene and the first tRNA gene or within the tRNA gene cluster. A terminator sequence was found directly after the last tRNA gene. This rRNA and tRNA gene cluster probably represents one transcriptional unit. However, there may be an RNA polymerase promoter site within this sequence, which raises some interesting questions concerning the regulation of transcription for these tRNA genes.
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PMID:Sequence analysis of a cluster of twenty-one tRNA genes in Bacillus subtilis. 631 May 12

Eukaryotic transfer RNA genes have two internal discontinuous control regions, the A and B blocks, which correspond approximately to the D-stem and the pseudo-U arm of tRNA. In reconstituted transcription systems at least two components are required to direct accurate initiation by RNA polymerase (refs 4,5). However, little is known about the mechanism of interaction of the internal promoter sequences with factors and RNA polymerase C within the transcription complex, although tRNA-like conformation of the B block sequence was surmised to be critical for DNA recognition. By analogy with the 5S RNA system, where a transcription factor required for 5S DNA expression was shown to interact both with 5S RNA and with the noncoding strand of the 5S gene, we explored the possibility that a protein which normally binds to tRNA could also interact with the tRNA gene and regulate its transcription. Here we show that in vitro transcription of the yeast SUP4 tRNATyr gene in crude yeast extracts is strongly stimulated by tyrosyl-tRNA synthetase (TyrRS) but not by two other non-cognate synthetases. Substrates of the synthetase, tRNATyr and tyrosine, interfere with stimulation of tRNA synthesis.
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PMID:Stimulation of transcription of the yeast tRNATyr gene in cell-free extracts by tyrosyl-tRNA synthetase. 635 Aug 90

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