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 role of the C-terminal Phe882-Ala883 residues of bacteriophage T7 RNA polymerase in specific transcription has been investigated by means of site-directed mutagenesis. A mutant enzyme that lacks the C-terminal Phe882-Ala883 residues, denoted the "foot" mutant, has been cloned and overproduced, and the effects of the deletion on promoter recognition, initiation, and elongation have been determined. Gel retardation assays and DNase I footprinting show that the foot mutant specifically recognizes and binds to T7 promoters, although this binding appears to be approximately 30-fold weaker than that of the wild-type enzyme. Transcription assays using oligonucleotide templates that contain the consensus T7 promoter show a dramatic decrease in transcriptional activity for the foot mutant. With templates whose coding region begins CCC..., the mutant synthesizes poly(G) products even in the presence of all four nucleotides. The synthesis of poly(G) products from such templates has previously been observed for the wild-type enzyme when GTP is the sole nucleotide present in the reaction and is thought to occur by a novel mechanism involving slippage of the RNA chain 3' to 5' relative to the template [Martin, C.T., Muller, D.K., & Coleman, J.E. (1988) Biochemistry 27, 3966-3974]. These data suggest that the loss in transcriptional activity by the foot mutant results from a severe decrease in processivity as well as catalytic efficiency of the enzyme. Removal of the C-terminal Phe and Ala residues from the wild-type enzyme with carboxypeptidase A generates the phenotype of the mutant precisely, proving that all of the properties of the foot mutant derive from the loss of the Phe-Ala-COOH moiety.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Processivity of T7 RNA polymerase requires the C-terminal Phe882-Ala883-COO- or "foot". 205 36

Host cell RNA synthesis is inhibited by poliovirus infection. We have studied the mechanism of poliovirus-induced inhibition of RNA polymerase II-mediated transcription by using the adenovirus early region 3 (E3) promoter. In vitro transcription from the E3 promoter was severely inhibited in extracts prepared from poliovirus-infected HeLa cells. Four regions in the E3 promoter have been shown to serve as binding sites for cellular transcription factors. These regions contain binding sites for transcription factors NF-1 (site IV), AP-1 (site III), CREB/ATF (site II), and the TATA factor (site I). Binding to these four regions was not significantly altered by poliovirus infection as assayed by DNase I footprinting analysis; furthermore, gel retardation assays failed to reveal dramatic differences in the total amount of CREB/ATF-, AP-1-, and NF-1-binding activity present in mock- or poliovirus-infected cell extracts. Gel retardation assays, however, did reveal significant qualitative differences in the DNA-protein complexes formed with a CREB/ATF-binding site in extracts prepared from poliovirus-infected cells as compared to mock-infected cell extracts. Radioimmunoprecipitation reactions performed with antiserum against CREB/ATF revealed a severe reduction in a phosphorylated form of the protein present in poliovirus-infected cell extracts. However, in vitro kinase reactions demonstrated that mock- and poliovirus-infected cell extracts contained similar levels of CREB/ATF. Expression from the E3 promoter was shown to be activated by CREB/ATF in vivo; this induction was dependent upon the phosphorylation of CREB/ATF. Thus, we propose that poliovirus infection inhibits transcription from the E3 promoter, at least in part, through the dephosphorylation of CREB/ATF.
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PMID:Loss of a phosphorylated form of transcription factor CREB/ATF in poliovirus-infected cells. 216 27

The human ADH1, ADH2, and ADH3 genes are closely related members of a gene family which are differentially expressed during liver development. To begin examining the mechanism of this tissue-specific and stage-specific expression, the 5'-flanking nucleotide (nt) sequences of the three genes were determined and the transcription start point (tsp) were identified. Sequences of all three genes indicated a high degree of homology (greater than 80% nt sequence identity) from the AUG translation start codon to about nt -780 relative to the tsp. Transient transfection assays of a set of plasmids containing various lengths of ADH 5'-flanking DNA fused to cat were performed in the HepG2 and Hep3B human hepatoma cell lines. The results indicated that the ADH2 promoter-proximal region was transcriptionally active in the absence of upstream sequences. To identify potential cis-acting elements in the ADH2 promoter-proximal region, a DNase I footprinting assay using a rat liver nuclear extract was used. Protection occurred in several locations including one, between nt -51 and -10, which shares homology with known binding sites for a previously identified rat-liver transcription factor called CCAAT/enhancer binding protein (C/EBP). Purified C/EBP was shown by footprint analysis to bind at two distinct sites in the ADH2 promoter located at nt -51 to -31 and -21 to -10. The TATA-box promoter element at nt -30 to -22 was not protected by C/EBP, but was partially protected by a factor in the rat liver nuclear extract. Thus, it is possible that the flanking C/EBP molecules may create a novel binding pocket for TFIID, the TATA-binding general transcription factor for RNA polymerase II. Alternatively, the C/EBP molecules may block access to the TATA box, and stimulate transcription of ADH2 by interacting with some component(s) other than TFIID.
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PMID:Promoters for the human alcohol dehydrogenase genes ADH1, ADH2, and ADH3: interaction of CCAAT/enhancer-binding protein with elements flanking the ADH2 TATA box. 216 44

During transcription, positive and negative superhelical stresses are generated on a DNA template which could potentially affect nucleosomal structure. When transcription was performed on a closed circular plasmid containing nucleosomes, using T7 RNA polymerase and topoisomerase I, nucleosomal structure was lost from the DNA. Nucleosome content was assayed by analyzing both the topological state of the DNA and the nuclease-resistant fragments produced by micrococcal nuclease and DNase I treatment. This nucleosome dissolution required positive superhelical stress as evidenced by the requirement that the extended RNA transcript remain associated with the polymerase during the transcription process. Rates of transcription were found to be independent of whether the nucleosomes dissolved. When transcription was performed in the absence of topoisomerase I, nucleosome reformation occurred very rapidly. This observation suggests that negative superhelical stress, induced in the wake of polymerase action, facilitates nucleosome reformation.
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PMID:In vitro evidence that transcription-induced stress causes nucleosome dissolution and regeneration. 217 Mar 57

A plasmid carrying a CRP-dependent promoter fused to the lac structural genes was manipulated to construct a set of spacing mutants that have varying lengths between the CRP binding site and the -35 region. The lengths of the spacer were changed over 45 bp by inserting or deleting nucleotides. DNase I footprinting analysis revealed that the spacer length did not affect the binding of cAMP-CRP to the CRP site. The effect of the spacer length on transcription activation by cAMP-CRP was tested in vivo by beta-galactosidase and quantitative S1 assays with crp+ and delta crp cells harboring plasmids. Insertions or deletions of non-integral helical turns, which displace the CRP site onto the opposite face of DNA helix compared to the original promoter, eliminated completely the activation of transcription. In contrast, changing the spacer length by integral helical turns allowed the promoter to respond to CRP, although the degree of activation varied with the length of the spacer. We conclude that stereospecific positioning of CRP and RNA polymerase on the DNA helix is strictly required for CRP action. The data support a model that CRP stimulates transcription by directly contacting RNA polymerase.
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PMID:Helical phase dependent action of CRP: effect of the distance between the CRP site and the -35 region on promoter activity. 217 26

The anti-alpha monoclonal antibody, mAb 126C6, has been used to investigate the role of the alpha subunit in transcription initiation. mAb 126C6 strongly inhibits cAMP-CRP-dependent abortive initiation with lac P+, partially inhibits abortive initiation with the lac L8UV5 promoter, and is without effect on the d(A-T)n-directed synthesis of r(A-U)n. DNase I footprinting shows that the preformed mAb 126C6-RNA polymerase complex does not bind to cAMP-CRP-lac P+; RNA polymerase specific protection is largely lost after incubation of the preformed RPo with mAb 126C6. Kinetic analysis of open complex formation by mAb 126C6-RNA polymerase with lac L8UV5 showed that changes in both the binding and the rate of isomerization account for the observed inhibition, with the isomerization step affected to a greater extent. Binding of cAMP-CRP to lac L8UV5 is RNA polymerase dependent. DNase I footprints show that as a consequence of mAb 126C6 binding of the preformed cAMP-CRP-lac L8UV5-RNA polymerase RPo, CRP dissociates from its site on the promoter. RNA polymerase protection of the promoter upstream from -41 is also lost. DNase I footprinting of mAb 126C6-RNA polymerase complexed with cAMP-CRP-lac P+ or -lac L8UV5 suggests that interactions between CRP and RNA polymerase are affected by binding of the anti-alpha mAb 126C6 to RNA polymerase. Protection methylation studies demonstrate that the formation of the mAb 126C6-RNA polymerase-lac L8UV5 open complex occurs at a slower rate and that nonoptimal contacts are established between mAb 126C6-RNA polymerase-lac L8UV5 promoter.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of an anti-alpha monoclonal antibody on interaction of Escherichia coli RNA polymerase with lac promoters. 219 Jun 32

Regulation of eukaryotic genes is largely governed by multiple cis-acting DNA sequences recognized by specific transcription factors. The transcription factor NF-kappa B has been implicated as an important regulator of cellular and viral genes, including those of immunoglobulin kappa light chain, interleukin-2, beta-interferon, HIV-1 and cytomegalovirus. We have analyzed the effect of increasing the number of NF-kappa B sites, located directly upstream from the TATA box. Four copies of the sequence gave a more than 100-fold stimulation relative to a single copy, suggesting that NF-kappa B proteins act synergistically to bring about this dramatic increase in transcription. By DNase I footprinting we demonstrated factor binding to two adjacent NF-kappa B sites in vitro. However, we found no evidence for co-operative binding to these DNA sites. We propose that the high transcriptional activity results from another type of co-operation, based on multiple weak interactions of the NF-kappa B factors with another component of the transcription apparatus, perhaps RNA polymerase II itself.
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PMID:Synergistic activation of transcription by multiple binding sites for NF-kappa B even in absence of co-operative factor binding to DNA. 219 80

In HeLa cells, RNA polymerase III (pol III)-mediated transcription is severely inhibited by poliovirus infection. This inhibition is due primarily to the reduction in transcriptional activity of the pol III transcription factor TFIIIC in poliovirus-infected cells. However, the specific binding of TFIIIC to the VAI gene B-box sequence, as assayed by DNase I footprinting, is not altered by poliovirus infection. We have used gel retardation analysis to analyze TFIIIC-DNA complexes formed in nuclear extracts prepared from mock- and poliovirus-infected cells. In mock-infected cell extracts, two closely migrating TFIIIC-containing complexes, complexes I and II, were detected in the gel retardation assay. The slower migrating complex, complex I, was absent in poliovirus-infected cell extracts, and an increase occurred in the intensity of the faster-migrating complex (complex II). Also, in poliovirus-infected cell extracts, a new, rapidly migrating complex, complex III, was formed. Complex III may have been the result of limited proteolysis of complex I or II. These changes in TFIIIC-containing complexes in poliovirus-infected cell extracts correlated kinetically with the decrease in TFIIIC transcriptional activity. Complexes I, II, and III were chromatographically separated; only complex I was transcriptionally active and specifically restored pol III transcription when added to poliovirus-infected cell extracts. Acid phosphatase treatment partially converted complex I to complex II but did not affect the binding of complex II or III. Dephosphorylation and limited proteolysis of TFIIIC are discussed as possible mechanisms for the inhibition of pol III-mediated transcription by poliovirus.
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PMID:A transcriptionally active form of TFIIIC is modified in poliovirus-infected HeLa cells. 220 7

The malate-aspartate shuttle, consisting of mitochondrial and cytosolic aspartate aminotransferase and mitochondrial and cytosolic malate dehydrogenase, is a major pathway for the transport of reducing equivalents from cytosol to mitochondria in mammals. To elucidate molecular mechanisms regulating metabolic coordination between the mitochondria and the cytosol, we analyzed the 5'-flanking regulatory regions of the complete set of mouse isoenzyme genes playing a pivotal role in the shuttle. Deletion analysis and an in vivo transfection assay, using NIH3T3 cells, revealed that all the promoter regions are located within the 300-base pair regions upstream from the initiation codon. Subsequently, DNase I footprinting analyses using NIH3T3 cell nuclear extracts led to identification of several protein binding sites within these promoter regions. A synthetic oligomer containing the consensus binding site sequence for CTF/NFI, a transcription factor for RNA polymerase II, competed for the binding of proteins to the promoter regions of cytosolic aspartate aminotransferase and mitochondrial and cytosolic malate dehydrogenase genes, but not for that of the mitochondrial aspartate amino-transferase gene. On the other hand, a synthetic oligomer containing the consensus binding site sequence for Sp1, which activates transcription from promoters containing properly positioned GC boxes, competed for protein(s) binding to the promoter region of the mitochondrial aspartate aminotransferase gene.
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PMID:Regulatory regions of the mitochondrial and cytosolic isoenzyme genes participating in the malate-aspartate shuttle. 229 30

We have identified a sequence element that specifies the position of transcription initiation for the dihydrofolate reductase gene. Unlike the functionally analogous TATA box that directs RNA polymerase II to initiate transcription 30 nucleotides downstream, the positioning element of the dihydrofolate reductase promoter is located directly at the site of transcription initiation. By using DNase I footprint analysis, we have shown that a protein binds to this initiator element. Transcription initiated at the dihydrofolate reductase initiator element when 28 nucleotides were inserted between it and all other upstream sequences, or when it was placed on either side of the DNA helix, suggesting that there is no strict spatial requirement between the initiator and an upstream element. Although neither a single Sp1-binding site nor a single initiator element was sufficient for transcriptional activity, the combination of one Sp1-binding site and the dihydrofolate reductase initiator element cloned into a plasmid vector resulted in transcription starting at the initiator element. We have also shown that the simian virus 40 late major initiation site has striking sequence homology to the dihydrofolate reductase initiation site and that the same, or a similar, protein binds to both sites. Examination of the sequences at other RNA polymerase II initiation sites suggests that we have identified an element that is important in the transcription of other housekeeping genes. We have thus named the protein that binds to the initiator element HIP1 (Housekeeping Initiator Protein 1).
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PMID:Transcription initiation from the dihydrofolate reductase promoter is positioned by HIP1 binding at the initiation site. 230 58

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