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)

An amber fragment of the beta subunit of Escherichia coli RNA polymerase has been recovered from strains carrying the rpoB12 amber mutation, indicating that the B12 mutation resides in the structural gene for the beta subunit. The fragment is readily assayed and can be used to determine the degree of expression of a single rpoB cistron in strains haploid or diploid for this region. These studies confirm that the bacterial mechanism, which can compensate for reduced translation of the beta message, operates by the co-ordinate induction of rpoB and rpoC. Furthermore, I show that rpo control depends upon cistron(s) located on the F' factor, KLF10, whose product(s) can act negatively in trans on rpoBC expression.
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PMID:Identification of an amber fragment of the beta subunit of Escherichia coli RNA polymerase: a yardstick for measuring controls on RNA polymerase subunit synthesis. 32 70

The zinc-binding subunits of yeast RNA polymerase A(I) and B(II) have been identified by a zinc-blotting technique. The two largest subunits of each enzyme (A190, A135, B220, and B150), as well as A12.2, A10, B44.5, B12.6, and B10, bind 65Zn(II). Predicted zinc-binding motifs have been noted in the NH2-terminal part of B220 and the COOH-terminal region of B150 subunits. Subdomains encompassing these motifs have been overproduced as MalE-fusion proteins and shown to retain zinc binding activity. Site-directed mutagenesis in the predicted metal-binding domain of B150 demonstrated its role in zinc binding. Mutations of cysteine residues C1163, C1166, C1182, and C1185 affected 65Zn2+ binding in vitro and caused a lethal or thermosensitive phenotype for growth. The ability to bind zinc is not sufficient for function since mutations in vicinal residues not affecting zinc binding were either lethal or thermosensitive. The role of zinc in RNA polymerase structure and function is discussed in the light of the present results.
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PMID:Zinc-binding subunits of yeast RNA polymerases. 193 19

We describe a cell-free transcription system for the archaebacterium Sulfolobus sp. B12 that specifically initiates transcription at the 5S rRNA-encoding DNA and the 16S/23S rRNA-encoding DNA promoters of the same species. With this crude extract system, specific initiation was absolutely dependent on the box A motif, a highly conserved promoter element in archaebacteria located approximately 25 base pairs upstream of transcription initiation sites. In vitro transcription of the rRNA genes by purified RNA polymerase, however, resulted in semi-specific, box A-independent initiation, indicating that factor(s) in the crude extract were necessary for the highly specific box A-dependent transcription. Fractionation of the cell-free extract by sucrose-gradient centrifugation resulted in the identification of a low molecular weight fraction complementing purified RNA polymerase to an extract-like specificity.
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PMID:In vitro transcription of two rRNA genes of the archaebacterium Sulfolobus sp. B12 indicates a factor requirement for specific initiation. 211 9

By using a recently developed in vitro transcription assay, the 16S/23S rRNA-encoding DNA promoter from the archaebacterium Sulfolobus sp. B12 was dissected by deletion and linker substitution mutagenesis. The analysis of 5' and 3' deletion mutants defined a core promoter region between positions -38 and -2 containing all information for efficient and specific transcription. Further characterization of this region by linker substitution mutagenesis indicated two sequence elements important for promoter function--one located between positions -38 and -25 (distal promoter element) and the other one located between positions -11 and -2 (proximal promoter element). The distal promoter element encompassed the TATA-like "box A" element located approximately 26 nucleotides upstream of the majority of transcription start sites in archaebacteria (Archaeobacteria). All mutations within this box A motif virtually abolished promoter function. Complete inactivation of the proximal promoter element was dependent on extensive mutagenesis; this element is not conserved between archaebacterial promoters except for a high A + T content in stable RNA gene promoters from Sulfolobus. Mutants containing insertions or deletions between the distal and proximal promoter elements were only slightly affected in their transcription efficiency but displayed a shift in their major initiation site, retaining an essentially fixed distance between the distal promoter element and the transcription start site. Thus, efficient transcription and start-site selection were dependent on a conserved TATA-like sequence centered approximately 26 nucleotides upstream of the initiation site, a situation unlike that of eubacterial promoters but resembling the core structure of most eukaryotic RNA polymerase II (and some RNA polymerase III) promoters. This finding suggests a common evolutionary origin of these promoters consistent with the known similarities between archaebacterial and eukaryotic RNA polymerases.
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PMID:Mutational analysis of an archaebacterial promoter: essential role of a TATA box for transcription efficiency and start-site selection in vitro. 212 95

We present homologies between archaeal and eucaryal DNA-dependent RNA polymerase (RNAP) subunits and transcription factors. The sequences of the Sulfolobus acidocaldarius subunits D, E, and N and alignments with eucaryal homologs are presented here. The similarities between archaeal transcription factors and their eucaryal homologs TFIIB and TBP have been established in other laboratories. The archaeal RNAP subunits H, K, and N, respectively, show high sequence similarity to ABC27, ABC23, and ABC10 beta (found in all three eucaryal RNAPs); subunit D, to AC40 (common to polymerase II and polymerase III) and B44 (polymerase II); and subunit L, to AC19 and B12.5. The similarity of subunit D and its eucaryal homologs to bacterial alpha is limited to the "alpha-motif," which is also present in subunit L and its eucaryal homologs. Genes encoding homologs of the related eucaryal RNAP subunits A12.2/B12.6 and also homologs of eucaryal transcription elongation factors of the TFIIS family have been detected in Sulfolobus acidocaldarius and Thermococcus celer. In archaea, the protein is not an RNAP subunit. Together with the sequence similarities between archaeal box A-containing and eucaryal TATA box-containing promoters, this shows that the archaeal and eucaryal transcription systems are truly homologous and that they differ structurally and functionally from the bacterial transcription machinery. In contrast, however, a number of genes for the archaeal transcription apparatus are organized in clusters resembling the clusters of transcription-associated genes in Bacteria.
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PMID:Transcription in archaea: similarity to that in eucarya. 759 27

Through random search, a gene from Thermococcus celer has been identified and sequenced that appears to encode a transcription-associated protein (110 amino acid residues). The sequence has clear homology to approximately the last half of an open reading frame reported previously for Sulfolobus acidocaldarius [Langer, D. & Zillig, W. (1993) Nucleic Acids Res. 21, 2251]. The protein translations of these two archaeal genes in turn are homologs of a small subunit found in eukaryotic RNA polymerase I (A12.2) and the counterpart of this from RNA polymerase II (B12.6). Homology is also seen with the eukaryotic transcription factor TFIIS, but it involves only the terminal 45 amino acids of the archaeal proteins. Evolutionary implications of these homologies are discussed.
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PMID:The sequence, and its evolutionary implications, of a Thermococcus celer protein associated with transcription. 817 Oct 1

We have previously isolated mutants of Saccharomyces cerevisiae that are primarily defective in transcription of 35S rRNA genes by RNA polymerase I and have identified genes (RRN1 to RRN9) involved in this process. We have now cloned the RRN4 gene by complementation of the temperature-sensitive phenotype of the rrn4-1 mutant and have determined its complete nucleotide sequence. The following results demonstrate that the RRN4 gene encodes the A12.2 subunit of RNA polymerase I. First, RRN4 protein expressed in Escherichia coli reacted with a specific antiserum against A12.2. Second, amino acid sequences of three tryptic peptides obtained from A12.2 were determined, and these sequences are found in the deduced amino acid sequence of the RRN4 protein. The amino acid sequence of the RRN4 protein (A12.2) is similar to that of the RPB9 (B12.6) subunit of yeast RNA polymerase II; the similarity includes the presence of two putative zinc-binding domains. Thus, A12.2 is a homolog of B12.6. We propose to rename the RRN4 gene RPA12. Deletion of RPA12 produces cells that are heat but not cold sensitive for growth. We have found that in such null mutants growing at permissive temperatures, the cellular concentration of A190, the largest subunit of RNA polymerase I, is lower than in the wild type. In addition, the temperature-sensitive phenotype of the rpa12 null mutants can be partially suppressed by RPA190 (the gene for A190) on multicopy plasmids. These results suggest that A12.2 plays a role in the assembly of A190 into a stable polymerase I structure.
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PMID:Gene RRN4 in Saccharomyces cerevisiae encodes the A12.2 subunit of RNA polymerase I and is essential only at high temperatures. 841 19

By means of the yeast two-hybrid system using the 40-kDa subunit of mouse RNA polymerase I, mRPA40, as the bait, we isolated a mouse cDNA which encoded a protein with significant homology in amino acid sequence to the 12.5-kDa subunit of Saccharomyces cerevisiae RNA polymerase II, B12.5 (RPB11). Specific antibody raised against the recombinant protein that was derived from the cDNA reacted with a 14-kDa polypeptide in highly purified mammalian RNA polymerase II and did not react with any subunit of RNA polymerase I or III. Moreover, the antibody co-immunoprecipitated the largest subunit of mouse RNA polymerase II. These results provide biochemical evidence that the cDNA isolated, named mRPB14, encodes a specific subunit of RNA polymerase II, and indicate that the subunit organization of the enzyme is conserved between yeast and mouse. A possible role of the alpha-motif [Dequard-Chablat, M., Riva, M., Carles, C. and Sentenac, A., J. Biol. Chem. 266 (1991) 15300-15307] in the protein-protein interaction between mRPA40 and mRPB14 is also discussed.
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PMID:Isolation and characterization of cDNA encoding mouse RNA polymerase II subunit RPB14. 909 76

Methionine synthase (MS) catalyses the methylation of homocysteine to methionine and requires the vitamin B12 derivative, methylcobalamin, as cofactor. We and others have recently cloned cDNAs for MS and described mutations associated with the cblG complementation group that correspond to MS deficiency. A subset of cblG, known as "cblG variant," shows no detectable MS activity and failure of [57Co]CN cobalamin to incorporate into MS in patient fibroblasts. We report the mutations responsible for three cblG-variant patients, two of them siblings, who presented with neonatal seizures, severe developmental delay, and elevated plasma homocysteine. Cell lines from all three patients were negative by northern blotting, though trace MS mRNA could be detected by means of phosphorimage analysis. Reverse transcriptase-PCR, SSCP, and nucleotide sequence analysis revealed four mutations. All were functionally null, creating either a frameshift with a downstream stop codon or an insert containing an internal stop codon. Of the two mutations found in the siblings, one of them, intervening sequence (IVS)-166A-->G, generates a cryptic donor splice site at position -166 of an intron beginning after Leu113, resulting in a 165-bp insertion of intronic sequence at junction 339/340. The second is a 2-bp deletion, 2112delTC. Mutations in the third patient include a G-->A substitution, well within the intron after Lys203, which results in intronic inserts of 128 or 78 bp in the mRNA. The second mutation is a 1-bp insertion, 3378insA. We conclude that the absence of MS protein in these cblG variants is due to mutations causing premature translation termination and consequent mRNA instability.
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PMID:Functionally null mutations in patients with the cblG-variant form of methionine synthase deficiency. 968 7

The level of the vitamin B12 transport protein BtuB in the outer membrane of Escherichia coli is strongly reduced by growth in the presence of cobalamins. Previous analyses of regulatory mutants and of btuB-lacZ fusions indicated that the primary site of btuB gene regulation was at the translational level, and this required sequences throughout the 240-nucleotide (nt) leader region. Cobalamin-dependent regulation of transcriptional fusions was of a lesser magnitude but required, in addition to the leader, sequences within the first 100 nt of the coding sequence, termed the translated regulatory region (TRR). To analyze the process of transcription-level regulation of btuB in E. coli, the levels and metabolism of btuB RNA were analyzed by S1 nuclease protection assays, and mutations that alter the coupling of translational and transcriptional control were analyzed. Expression of transcriptional fusions was found to correlate with changes in the level of intact btuB RNA and was related to changes in the metabolic stability of the normally long-lived RNA. Mutational analysis showed that the btuB start codon and a hairpin structure that can sequester the Shine-Dalgarno sequence are necessary for cobalamin-dependent regulation and that translation of the TRR is necessary for extended RNA stability and for expression of the transcriptional fusion. The absence of regulation at the stage of transcription initiation was confirmed by the findings that several truncated btuB RNA fragments were expressed in a constitutive manner and that the normal regulatory response occurred even when the btuB promoter and upstream sequences were replaced by the heterologous bla and lac promoters. Transcription driven by phage T7 RNA polymerase was not regulated by cobalamins, although some regulation at the translational level was retained. Cobalamin-dependent changes in RNA structure were suggested from the RNase III-dependent production of a transcript fragment that is made only in the presence of cobalamin and is independent of the regulatory outcome. These results indicate that the primary control of btuB expression by cobalamin occurs at the level of translation initiation, which directly affects the level and stability of btuB RNA in a process that requires the presence of the intact translated regulatory region.
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PMID:Coupled changes in translation and transcription during cobalamin-dependent regulation of btuB expression in Escherichia coli. 985 20

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