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)

Escherichia coli RNA Polymerase is a multi-subunit enzyme that catalyzes RNA synthesis, using DNA as a template. The sigma subunit of this enzyme plays an important role in the recognition of promoter sites on DNA. Using DNase I footprinting, we have found that in the absence of the other subunits, sigma binds specifically to the bacteriophage lambda PR promoter DNA sequence. In the presence of the sigma subunit alone, a protective footprint encompassing the region between residue positions -41 and +17 was observed (where +1 is the transcription start site). The holoenzyme gave a footprint covering the same region. Thus not only does the sigma subunit interact with the DNA promoter site in the absence of the other components of RNA polymerase, but also the footprint of sigma is indistinguishable from that of the holoenzyme.
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PMID:Footprint of the sigma protein. 252 2

The rpoH (htpR) gene of Escherichia coli encodes a sigma factor which confers upon RNA polymerase the ability to recognize the promoters for genes responsive to the phenomenon termed the heat shock response. dnaA protein, a sequence-specific DNA binding protein, is required for initiation of chromosomal replication by binding to sites within the chromosomal origin. dnaA protein also autoregulates its expression by binding to a site in the dnaA promoter region. Two copies of the dnaA protein recognition sequence are present within the rpoH promoter region. Using filter binding assays, dnaA protein was observed to bind specifically to DNA fragments containing the rpoH promoter region with greater affinity than its binding to the dnaA promoter region. By contrast, reduced binding to a DNA fragment containing the lacUV5 promoter was observed. DNase I footprint analysis indicated that dnaA protein protected specific sites within the rpoH promoter region. The binding of dnaA protein to the rpoH promoter region resulted in transcriptional repression from two of the three promoters of the rpoH gene in vitro. Elevated levels of dnaA protein repressed transcription from these two rpoH promoters in vivo. These results indicate that dnaA protein regulates rpoH transcription to influence the expression of genes under rpoH control.
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PMID:dnaA protein regulates transcriptions of the rpoH gene of Escherichia coli. 254 Jan 87

The interactions of T7 RNA polymerase with its promoter DNA have been previously probed in footprinting experiments with either DNase I or (methidiumpropyl-EDTA)-Fe(II) to cleave unprotected DNA [Basu, S., & Maitra, U. (1986) J. Mol. Biol. 190, 425-437. Ikeda, R. A., & Richardson, C. C. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 3614-3618]. Both of these reagents have drawbacks; DNase I is a bulky reagent and so provides low resolution, and (methidiumpropyl-EDTA)-Fe(II) intercalates into DNA and is therefore biased toward cleavage of double-stranded DNA. In this study, the interaction between the polymerase and the promoter has been probed with Fe(II)-EDTA. This reagent generates reactive hydroxyl radicals free in solution, which produces a more detailed picture of the polymerase-promoter complex. Two protected regions are observed on each of the two promoter DNA strands: from position -17 to position -13 and from position -7 to position -1 on the coding strand and from position -14 to position -9 and from position -3 to position +2 on the noncoding strand. From this pattern it is clear that if recognition occurs via double-stranded B-form DNA, then the protected regions lie on one face of the DNA helix, and therefore the enzyme must interact predominantly from one side of the DNA helix. Digestion of the DNA in a polymerase-promoter complex with a single-strand-specific endonuclease shows that a small region of the noncoding strand near position -5 is susceptible to cleavage.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:T7 RNA polymerase interacts with its promoter from one side of the DNA helix. 254 54

The P1 RepA protein appears to play three roles in P1 plasmid replication: acting at the origin both as a specific initiator and as a repressor of transcription, and interacting with the copy-control locus incA to bring about a negative control of initiation. We have used the DNase I footprinting technique to show that RepA binds specifically to repeat units of a 19-base-pair consensus sequence present in both the origin and incA control regions. RNA polymerase was shown to bind to two specific regions within the origin repeats. One of these constitutes the known promoter sequence for the repA gene. We show evidence that the polymerase can be efficiently displaced from the promoter by subsequent RepA binding, thus providing a direct mechanism for RepA autoregulation. Under the conditions used, there were no obvious differences in the affinities of individual repeat sequences for the purified protein.
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PMID:Protein-DNA interactions in regulation of P1 plasmid replication. 264 99

The molecular basis for the greatly elevated expression of the cir gene (encoding the colicin I receptor) in cells unable to maintain a critical supply of intracellular iron was investigated by genetic and biochemical means. Deletion analysis of the cloned promoter region allowed delineation of sequences necessary for control of transcription initiating at the two promoters, P1 and P2. Gel retardation assays were used to demonstrate both binding of purified Fur (ferric uptake regulation) protein to the iron control region and lack of binding to DNA fragments which are not involved in cir regulation. An operator sequence spanning 43 to 47 base pairs and completely encompassing the two promoters was identified by DNase I protection experiments (footprinting), with binding occurring in a metal-dependent fashion. Thus, during iron-replete growth, Fur appears to act as a repressor of transcription by blocking formation of a DNA-RNA polymerase complex, analogous to the mechanism previously described for regulation of the aerobactin operon (V. de Lorenzo, S. Wee, M. Herrero, and J.B. Neilands, J. Bacteriol. 169:2624-2630, 1987). Characterized and putative Fur recognition sites from several genes were analyzed and classified by statistical methods.
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PMID:Mechanism for iron-regulated transcription of the Escherichia coli cir gene: metal-dependent binding of fur protein to the promoters. 264 21

The Ada protein of Escherichia coli catalyzes transfer of methyl groups from methylated DNA to its own molecule, and the methylated form of Ada protein promotes transcription of its own gene, ada. Using an in vitro reconstituted system, we found that both the sigma factor and the methylated Ada protein are required for transcription of the ada gene. To elucidate molecular mechanisms involved in the regulation of the ada transcription, we investigated interactions of the non-methylated and methylated forms of Ada protein and the RNA polymerase holo enzyme (the core enzyme and sigma factor) with a DNA fragment carrying the ada promoter region. Footprinting analyses revealed that the methylated Ada protein binds to a region from positions -63 to -31, which includes the ada regulatory sequence AAAGCGCA. No firm binding was observed with the non-methylated Ada protein, although some DNase I-hypersensitive sites were produced in the promoter by both types of Ada protein. RNA polymerase did bind to the promoter once the methylated Ada protein had bound to the upstream sequence. To correlate these phenomena with the process in vivo, we used the DNAs derived from promoter-defective mutants. No binding of Ada protein nor of RNA polymerase occurred with a mutant DNA having a C to G substitution at position -47 within the ada regulatory sequence. In the case of a -35 box mutant with a T to A change at position -34, the methylated Ada protein did bind to the ada regulatory sequence, yet there was no RNA polymerase binding. Thus, the binding of the methylated Ada protein to the upstream region apparently facilitates binding of the RNA polymerase to the proper region of the promoter. The Ada protein possesses two known methyl acceptor sites, Cys69 and Cys321. The role of methylation of each cysteine residue was investigated using mutant forms of the Ada protein. The Ada protein with the cysteine residue at position 69 replaced by alanine was incapable of binding to the ada promoter even when the cysteine residue at position 321 of the protein was methylated. When the Ada protein with alanine at position 321 was methylated, it acquired the potential to bind to the ada promoter. These results are compatible with the notion that methylation of the cysteine residue at position 69 causes a conformational change of the Ada protein, thereby facilitating binding of the protein to the upstream regulatory sequence.
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PMID:Regulation of expression of the ada gene controlling the adaptive response. Interactions with the ada promoter of the Ada protein and RNA polymerase. 264 1

Multiple stages of protein-DNA interaction in the assembly of RNA polymerase III transcription complexes on a Saccharomyces cerevisiae 5S rRNA gene have been distinguished by DNase I "footprinting" and gel retardation. Transcription factor IIIA interacts with approximately 35 base pairs of the internal promoter region. Transcription factors IIIC and IIIB incrementally extend the interaction along the 5S gene, if, and only if, transcription factor IIIA is also bound. Complexes assembled from the complete set of purified transcription factors or from a complete transcription system extend over the entire transcription unit together with almost 50 base pairs of 5' flanking sequence.
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PMID:Multiple states of protein-DNA interaction in the assembly of transcription complexes on Saccharomyces cerevisiae 5S ribosomal RNA genes. 264 82

BlaI repressor for the beta-lactamase gene (blaP) of Bacillus licheniformis 749, was shown to repress expression of blaP and of the repressor gene (blaI), using the purified protein in a DNA-directed in vitro translation assay. Binding of BlaI to the promoter regions of blaP and blaI was examined by equilibrium and competitive binding assays. BlaI binds to the blaP promoter with an equal or only slightly higher affinity than to the blaI promoter. DNase I footprinting shows that BlaI binds directly to the blaP and blaI promoters, such that RNA polymerase binding and/or transcript elongation would be blocked.
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PMID:Interaction of BlaI, the repressor for the beta-lactamase gene of Bacillus licheniformis, with the blaP and blaI promoters. 265 Nov 54

By a series of conventional chromatographic procedures we have purified from whole-cell extracts of Saccharomyces cerevisiae yeast transcription factor IID (TFIID), which functionally substitutes for human TFIID in a complementation assay comprised of the adenovirus type 2 major late promoter and HeLa cell-derived RNA polymerase II, transcription factors IIA, IIB, and IIE. Similar to its human counterpart, yeast TFIID also exhibited specific binding to the adenovirus type 2 major late promoter TATA element, as shown by both DNase I footprinting and gel mobility shift assays. NaDodSO4/PAGE analyses showed that a 27-kDa polypeptide coeluted with TFIID complementing activity through each chromatographic step. In agreement with this result and also suggesting that the native protein is a monomer, gel-filtration experiments indicated a molecular mass of 28 kDa for TFIID under nondenaturing conditions. That the 27-kDa polypeptide represented TFIID was further demonstrated by the ability of an HPLC-purified protein to bind specifically after renaturation to the adenovirus type 2 major late promoter TATA sequence.
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PMID:Purification of a yeast TATA box-binding protein that exhibits human transcription factor IID activity. 266 84

The Escherichia coli galactose operon contains an unusual array of closely spaced binding sites for proteins governing the expression from the two physically overlapping gal promoters. Based on studies of two gal promoter-up mutants we have previously suggested RNA-polymerase-induced DNA bending of gal promoter DNA. Here we present new evidence confirming and extending this interpretation. It was obtained by the circular permutation assay of gel electrophoretic mobility [Wu and Crothers (1984), Nature, 308, 509-513] applied to three analogous series of circularly permuted fragments derived from wild-type and two promoter-up mutant DNAs. The same circularly permuted DNA fragments have further been used to study the binding of gal repressor to its operator sites by electrophoretic mobility shift and by DNase I footprinting techniques. The main results are: (i) complexes carrying repressor either exclusively at the upstream operator O1 or at the downstream operator O2 exhibit different electrophoretic mobilities; (ii) binding to either one of the operators results in protein-induced DNA bending by the criteria of the circular permutation mobility assay; and (iii) occupation of both gal operators by gal repressor does not prevent cAMP-CRP-independent binding of RNA polymerase to the gal promoters, as judged by DNase I protection and gel retardation assays. The latter finding imposes constraints on any attempt to model the regulation of gal expression by assumed DNA-protein and protein-protein interactions.
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PMID:RNA polymerase and gal repressor bind simultaneously and with DNA bending to the control region of the Escherichia coli galactose operon. 266 72

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