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)

The enteric NtrC (NRI) protein has been the paradigm for a class of bacterial enhancer-binding proteins (EBPs) that activate transcription of RNA polymerase containing the sigma 54 factor. Activators in the NtrC class are characterized by essentially three properties: (i) they bind to sites distant from the promoters that they activate (> 100 bp upstream of the transcriptional start site), (ii) they contain a conserved nucleotide-binding fold and exhibit ATPase activity that is required for activation, and (iii) they activate the sigma 54 RNA polymerase. We have characterized the NtrC protein from a photosynthetic bacterium, Rhodobacter capsulatus, which represents a metabolically versatile group of bacteria found in aquatic environments. We have shown that the R. capsulatus NtrC protein (RcNtrC) binds to two tandem sites that are distant from promoters that it activates, nifA1 and nifA2. These tandem binding sites are shown to be important for RcNtrC-dependent nitrogen regulation in vivo. Moreover, the conserved nucleotide-binding fold of RcNtrC is required to activate nifA1 and nifA2 but is not required for DNA binding of RcNtrC to upstream activation sequences. However, nifA1 and nifA2 genes do not require the sigma 54 for activation and do not contain the highly conserved nucleotides that are present in all sigma 54-type, EBP-activated promoters. Thus, the NtrC from this photosynthetic bacterium represents a novel member of the class of bacterial EBPs. It is probable that this class of EBPs is more versatile in prokaryotes than previously envisioned.
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PMID:A new type of NtrC transcriptional activator. 792 86

Fifty-eight cDNA clones isolated from a library of transcripts exhibiting up regulation in tomato root giant cells induced by infection with the parasitic nematode Meloidogyne incognita were characterized. A survey of plant tissues identified 31 transcripts present in tissues other than root, including actively dividing and expanding tissues and mature leaf tissues. The identities of approximately 20% of the giant cell transcripts were inferred from DNA sequence data; they include sequences encoding a plasmalemma proton ATPase, a putative Myb-type transcription factor, and the largest subunit of RNA polymerase II.
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PMID:DNA sequence and expression analysis of root-knot nematode-elicited giant cell transcripts. 801 51

Escherichia coli Rho factor is required for termination of transcription at certain sites by RNA polymerase. Binding to unstructured cytosine-containing RNA target sites, subsequent RNA-dependent ATP hydrolysis, and an RNA-DNA helicase activity that presumably facilitates termination, are considered essential for Rho function. Yet the RNA recognition elements have remained elusive, the parameters relating RNA binding to ATPase activation have been obscure, and the mechanistic steps that integrate Rho's characteristics with its termination function in vitro and in vivo have been largely undefined. Recent work offers new insights into these interactions with results that are both surprising and satisfying in the context of Rho's emerging structure. These include the requirements for binding and ATPase activation by a variety of RNA substrates, dynamic analyses of Rho tracking, helicase and termination activity, and the participation of a new factor (NusG) that interacts with Rho. Models for Rho function are considered in the light of these recent revelations.
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PMID:Rho and RNA: models for recognition and response. 802 88

Coding sequences from maize, rice, tobacco, and liverwort chloroplasts are aligned and subjected to relative rate tests. Results of rate tests suggest that coding sequences from maize and rice are evolving with homogeneous rates of nucleotide substitution while coding sequences from the grass lineages (i.e., maize and rice) are evolving at a faster rate than coding sequences from the tobacco chloroplast. Rate tests also suggest that particular loci evolve at significantly faster rates in grass chloroplast genomes than the tobacco chloroplast genome. These loci encode proteins important to RNA polymerase, the H(+)-ATPase complex, and the ribosomal proteins. Much of the variation at these loci can be attributed to differences in nonsynonymous substitution rates. Taken together, these studies suggest that the chloroplast DNA molecular clock varies both between evolutionary lineages and between protein coding loci.
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PMID:Relative rates of nucleotide substitution in the chloroplast genome. 804 49

The dctD gene product (DCTD) activates transcription from dctA by the sigma 54-holoenzyme form of RNA polymerase in Rhizobium meliloti. We have purified a constitutively active form of R. meliloti DCTD that lacks 142 amino acid residues from the N terminus (designated DCTDL143). Purified DCTDL143 recognized the DCTD-binding sites at the dctA promoter region and catalyzed the isomerization of closed complexes between sigma 54-holoenzyme and the dctA promoter to open complexes. Like the related sigma 54-dependent activators NTRC and NIFA, a purine nucleoside triphosphate with a hydrolyzable beta-gamma bond was required prior to transcription initiation for this isomerization. DCTDL143 hydrolyzed purine nucleoside triphosphates but not pyrimidine nucleoside triphosphates. As observed with NTRC-phosphate, the specific activity for the ATPase of DCTDL143 was strongly dependent on the enzyme concentration and was stimulated by DNA fragments bearing the binding sites for the protein. These DNA fragments increased the Vmax for MgATP hydrolysis but did not significantly lower the apparent Km for MgATP. These data are consistent with the idea proposed for related activators that DCTDL143 must assemble into an active, oligomeric form before it can hydrolyze MgATP and presumably activate transcription.
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PMID:Constitutive ATP hydrolysis and transcription activation by a stable, truncated form of Rhizobium meliloti DCTD, a sigma 54-dependent transcriptional activator. 805 Nov 35

The hrp/hrmA gene cluster of Pseudomonas syringae pv. syringae Pss61 has been shown to form a minimum genetic unit sufficient to enable nonpathogenic bacteria, such as Escherichia coli, to elicit the hypersensitive response associated with disease resistance. The biochemical functions of most of these genes have not been established. The nucleotide sequence of a 4.3-kb SstI-BglII fragment carrying hrp apparent translational units V, VI, and VII revealed one partial open reading frame (ORF) and five complete ORFs producing 35,126-, 48,866-, 17,308-, 20,482-, and 26,364-Da gene products (hrpJ3, J4, J5, U1, U2, respectively). The production of these proteins was confirmed by using T7 RNA polymerase-directed expression. The partial ORF was found to be identical to the C terminus of HrpJ2. The absence of apparent transcriptional terminators and promoters between hrpI (hrpJ2), hrpJ3, hrpJ4, and hrpJ5 together with the observation that the HrpL-dependent hrpJ promoter directs expression of hrpJ3-J5 indicates that these genes form a single operon controlled by the HrpL-dependent hrpJ promoter. A second HrpL-dependent promoter consensus sequence was also identified upstream of hrpU1 and demonstrated to function as a HrpL-dependent promoter, thus indicating that hrpU1, hrpU2, and additional downstream genes may be part of a second operon. The deduced product of hrpJ3 exhibits similarity to FliG of Salmonella typhimurium, a cytoplasmic protein that regulates flagellar rotation and biogenesis. HrpJ4 shares extensive similarity with the FliI family of ATPase-like proteins and retains the known functional domains conserved among this family of proteins. HrpJ5 has properties similar to the S. typhimurium FliJ. Neither HrpU1 nor HrpU2 exhibit significant similarity to known proteins. Secretion of HarpinPss by E. coli MC4100 transformants carrying pHIR11::TnphoA derivatives was blocked in hrpJ4, J5, and U2 mutants. In view of the previously reported similarity of HrpJ2 to the LcrD super-family that includes FlhA, these results predict that the gene products of the hrpJ and hrpU operons form an inner membrane complex for translocation of proteins similar to that used by the flagellar biogenesis system of S. typhimurium.
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PMID:Characterization of the hrpJ and hrpU operons of Pseudomonas syringae pv. syringae Pss61: similarity with components of enteric bacteria involved in flagellar biogenesis and demonstration of their role in HarpinPss secretion. 807 21

A predominant form of the inherited syndrome xeroderma pigmentosum is genetic complementation group C (XP-C). XP-C cells are defective in DNA nucleotide excision repair in the bulk of the genome but can repair transcribed strands of active genes. An activity that can complement the repair deficiency of extracts from XP-C cells has been purified approximately 2,000-fold from HeLa cells. The factor also increases the unscheduled DNA synthesis of XP-C fibroblasts in vivo after microinjection. Hydrodynamic measurements show that the XP-C complementing factor has a native molecular mass of approximately 160 kDa. The factor binds tightly to single-stranded DNA cellulose, eluting in approximately 1.3 M NaCl. No incision or ATPase activity of the protein alone was detected. XP-C protein is involved in an early stage of repair since its presence was required before the start of gap-filling repair synthesis. In vitro complementation was achieved with naked DNA substrates, and so a primary role in processing chromatin to allow access for repair enzymes seems unlikely. Surprisingly, however, extracts from an XP-C cell line introduced some incisions in UV-irradiated DNA; these were unstable in cell extracts and did not lead to complete repair. The data can be explained by a model in which XP-C factor participates in forming one of the repair incisions flanking DNA damage but not the other. In transcribed DNA, its role is subsumed by RNA polymerase and/or transcription coupling factors.
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PMID:DNA repair defect in xeroderma pigmentosum group C and complementing factor from HeLa cells. 807 26

When expression of the vaccinia virus gene encoding RAP94 (a protein that is associated with the viral multisubunit RNA polymerase and confers transcriptional specificity for early promoters) was repressed, the infectious virus yield was reduced by more than 99%. Nevertheless, intermediate- and late-stage viral gene expression and formation of ultrastructurally mature, membrane-enveloped virions occurred under the nonpermissive conditions. The RAP94-deficient particles contained the viral genome, structural proteins, early transcription factor, and certain enzymes but, unlike normal virions, had low or undetectable amounts of the viral RNA polymerase, capping enzyme/termination factor, poly(A) polymerase, DNA-dependent ATPase, RNA helicase, and topoisomerase. The presence of these viral enzymes in the cytoplasm indicated that RAP94 is required for targeting a complex of functionally related proteins involved in the biosynthesis of mRNA.
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PMID:Targeting of a multicomponent transcription apparatus into assembling vaccinia virus particles requires RAP94, an RNA polymerase-associated protein. 810 1

The vaccinia virus D6R open reading frame encodes the small subunit of the heterodimeric vaccinia virus early transcription factor (VETF) that activates transcription of early genes in vitro. VETF binds early gene promoters and has a DNA-dependent ATPase activity that is essential for activation of transcription. To examine the relationship between the structure and function of VETF, we have localized the mutations in two temperature-sensitive viruses whose lesions previously were mapped to the D6R gene. For both mutants, a single G-to-A nucleotide change that would alter protein coding potential was identified. In mutant E93, the codon for alanine 25 was changed to that of threonine, and in mutant S4 the codon for valine 278 was replaced with that for methionine. The molecular phenotype of each mutant was assessed by expressing mutant transcription factors in HeLa cells by using a vaccinia virus-T7 system and characterizing the proteins' activities in vitro. The A25T mutant activated transcription to a lesser extent than wild-type VETF, and the V278M mutant had no demonstrable transcription factor activity. Both mutant proteins were shown to be defective for promoter binding, accounting for their impairment in transcription activation. The functional defects for both mutants were observed at permissive as well as nonpermissive temperatures. The mutant proteins retained ATPase activity but required higher DNA concentrations to activate the ATPase. These results indicate that the small subunit of VETF is essential for its promoter binding activity and likely contacts the promoter DNA. Immunoblotting experiments showed that the virion particles from the two mutant viruses contained about half the VETF of wild-type virus, suggesting that promoter binding may contribute to packaging of VETF into the virion particle. RNA polymerase, mRNA capping enzyme, and nucleoside triphosphate phosphohydrolase I were found at similarly reduced levels in the virion, indicating that packaging of some virion core enzymes may be interdependent.
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PMID:Temperature-sensitive mutations in the gene encoding the small subunit of the vaccinia virus early transcription factor impair promoter binding, transcription activation, and packaging of multiple virion components. 813 39

The general transcription factor TFIIE, together with other general transcription factors, is essential for transcription initiation by RNA polymerase II. TFIIE stimulates the TFIIH-dependent kinase activity that phosphorylates the carboxy-terminal domain of the largest subunit of RNA polymerase II, and possesses a helicase activity. Here we show that human TFIIH has DNA-dependent ATPase activity and we characterize the stimulatory effect of TFIIE on both the ATPase and kinase activities. We demonstrate that extensive phosphorylation of RNA polymerase II occurs in a TFIIE-dependent manner in both the absence and presence of DNA but, in the latter case, only at a late stage of preinitiation complex assembly. We also show that TFIIH specifically phosphorylates three general transcription factors, human TFIID tau (TBP), TFIIE-alpha and TFIIF-alpha (RAP74).
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PMID:Regulation of TFIIH ATPase and kinase activities by TFIIE during active initiation complex formation. 816 91

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