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)

Yeast transcription factor tau (transcription factor IIIC) specifically interacts with tRNA genes, binding to both the A block and the B block elements of the internal promoter. To study the influence of A block-B block spacing, we analyzed the binding of purified tau protein to a series of internally deleted yeast tRNA(3Leu) genes with A and B blocks separated by 0 to 74 base pairs. Optimal binding occurred with genes having A block-B block distances of 30-60 base pairs; the relative helical orientation of the A and B blocks was unimportant. Results from DNase I "footprinting" and lambda exonuclease protection experiments were consistent with these findings and further revealed that changes in A block-B block distance primarily affect the ability of tau to interact with A block sequences; B block interactions are unaltered. When the A block-B block distance is 17 base pairs or less, tau interacts with a sequence located 15 base pairs upstream of the normal A block, and a new RNA initiation site is observed by in vitro transcription. We propose that the initial binding of tau to the B block activates transcription by enhancing its ability to bind at the A block, and that the A block interaction ultimately directs initiation by RNA polymerase III.
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PMID:Gene size differentially affects the binding of yeast transcription factor tau to two intragenic regions. 282 54

The DNA-sequence specificity of daunomycin was investigated by DNase I footprinting and an E. coli RNA polymerase transcription-inhibition assay. The 5'-CA sequence was identified as being the highest affinity binding site, although other modest affinity (5'-GC, CG, CT, TC, AC) and poor affinity sites (5'-AA, AT, TA) were also observed. The preference of daunomycin for 5'-CA nucleotide sequence suggests that its biological activity may arise from association with the 5'-CA-containing sequences thought to be associated with genetic regulatory elements in eukaryotes.
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PMID:The 5'-CA DNA-sequence preference of daunomycin. 282 15

Transcription initiation of the hisA gene in vivo in the archaebacterium Methanococcus vannielii, as determined by nuclease S1 and primer extension analyses, occurs 73 base pairs (bp) upstream of the translation initiation site. Binding of M. vannielii RNA polymerase protects 43 bp of DNA, from 35 bp upstream (-35) to 8 bp downstream (+8) of the hisA mRNA initiation site, from digestion by DNase I and exonuclease III. An A + T rich region, with a sequence which conforms to the consensus sequence for promoters of stable RNA-encoding genes in methanogens, is found at the same location (-25) upstream of the polypeptide-encoding hisA gene. It appears therefore that a TATA-like sequence is also an element of promoters which direct transcription of polypeptide-encoding genes in this archaebacterium.
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PMID:An archaebacterial RNA polymerase binding site and transcription initiation of the hisA gene in Methanococcus vannielii. 282 15

Four cAMP-independent receptor protein mutants (designated CRP* mutants) isolated previously are able to activate in vivo gene transcription in the absence of cAMP and their activity can be enhanced by cAMP or cGMP. One of the four mutant proteins, CRP*598 (Arg-142 to His, Ala-144 to Thr), has been characterized with regard to its conformational properties and ability to bind to and support abortive initiation from the lac promoter. In the absence of cGMP, CRP*598 shows a more open conformation than CRP, as indicated by its sensitivity to proteolytic attack and 5,5'-dithiobis(2-nitrobenzoic acid)-mediated subunit crosslinking. Binding of wild-type CRP to its site on the lac promoter and activation of abortive initiation by RNA polymerase on this promoter are effected by cAMP but not by cGMP. CRP*598 can activate lacP+-directed abortive initiation in the presence of cAMP and less efficiently in the presence of cGMP or in the absence of cyclic nucleotide. DNase I protection ("foot-printing") indicates that cAMP-CRP* binds to its site on the lac promoter whereas unliganded CRP* and cGMP-CRP* form a stable complex with the [32P]lacP+ fragment only in the presence of RNA polymerase, showing cooperative binding of two heterologous proteins. This cooperative binding provides strong evidence for a contact between CRP and RNA polymerase for activation of transcription. Although cGMP binds to CRP, it cannot replace cAMP in effecting the requisite conformational transition necessary for site-specific promoter binding. In contrast, the weakly active unliganded CRP*598 can be shifted to a functional state not only by cAMP but also by cGMP and RNA polymerase.
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PMID:Cooperative DNA binding of heterologous proteins: evidence for contact between the cyclic AMP receptor protein and RNA polymerase. 283 57

The virC and virD operons of the virulence region of the Ti plasmid are highly regulated, requiring a transcriptional regulator that is encoded by virG and is activated by the product of virA and plant phenolics such as acetosyringone. Full expression of virC and virD of octopine and nopaline Ti plasmids is also obtained by a mutation in the ros gene of the Agrobacterium tumefaciens chromosome. S1-nuclease analysis, in vitro transcription, and DNase I protection experiments with A. tumefaciens RNA polymerase revealed virD promoters tandemly arranged, both of which are functional in the Ros mutant, while only one is functional in the presence of acetosyringone. A third (overlapping) promoter appears to be responsible for transcription of virC. Expression of virC and virD appears to be modulated by factors within the bacterium by means of a mechanism that is independent of factors produced during infection of the host plant.
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PMID:Regulation of the virC and virD promoters of pTiC58 by the ros chromosomal mutation of Agrobacterium tumefaciens. 284 May 54

Promoters were isolated at random from the genome of Saccharomyces cerevisiae by using a plasmid that contains a divergently arrayed pair of promoterless reporter genes. A comprehensive library was constructed by inserting random (DNase I-generated) fragments into the intergenic region upstream from the reporter genes. Simple in vivo assays for either reporter gene product (alcohol dehydrogenase or beta-galactosidase) allowed the rapid identification of promoters from among these random fragments. Poly(dA-dT) homopolymer tracts were present in three of five randomly cloned promoters. With two exceptions, each RNA start site detected was 40 to 100 base pairs downstream from a TATA element. All of the randomly cloned promoters were capable of activating reporter gene transcription bidirectionally. Interestingly, one of the promoter fragments originated in a region of the S. cerevisiae rDNA spacer; regulated divergent transcription (presumably by RNA polymerase II) initiated in the same region.
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PMID:Properties of promoters cloned randomly from the Saccharomyces cerevisiae genome. 284 31

Expression of the melR gene is required for melibiose-dependent stimulation of transcription initiation at the promoter of the melAB operon. Using the S1 nuclease method we have located the melR transcription start point. Transcription from the melR promoter is dependent on cAMP-CRP: specific nucleotide sequences downstream of bp -59 with respect to the melR transcription start are sufficient for full promoter activity. Nucleotide sequence homologies suggest that the cAMP-CRP binding site is located from bp -52 to -31, in exactly the same position as at the galP1 promoter. Using DNase I footprinting we show that cAMP-CRP and RNA polymerase together bind tightly to the melR promoter sequence, creating a strong footprint from bp -70 to +20. Alone, cAMP-CRP binding is hardly detectable, whereas RNA polymerase alone creates a weak footprint centred around the -10 hexamer sequence. When the melR gene is expressed from a cAMP-CRP-independent promoter, melibiose-dependent transcription from the melAB promoter becomes independent of cAMP-CRP, showing that the melR promoter is the primary site of control by cAMP-CRP in the mel regulon.
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PMID:Transcription from the Escherichia coli melR promoter is dependent on the cyclic AMP receptor protein. 285 97

Bacteriophage T3 and T7 RNA polymerases are monomeric proteins of Mr of about 100,000. Each polymerase has stringent specificity for its own promoters that is present only on the homologous phage DNA template. Neither enzyme recognizes the heterologous phage promoters or Escherichia coli RNA polymerase promoters. In the present study, the interaction of T3 and T7 RNA polymerases with their respective cognate promoters was studied by DNase I footprinting techniques. These studies revealed an absolute requirement for the initiating nucleotide (GTP) for each phage RNA polymerase to bind specifically to and protect its cognate promoter from DNase I digestion. In the absence of the initiating nucleotide, both enzymes randomly bind DNA with lower affinity. No other nucleotide can substitute for GTP; however, the addition of GTP + ATP, which causes the synthesis of a hexamer RNA (pppGpGpGpApGpA), makes the DNA-RNA-protein complex highly stable. Nitrocellulose filter binding studies confirmed these observations. On the basis of these results we propose that the binding of the initiating nucleotide (in this case, GTP) drives the phage RNA polymerase into an "initiation conformation" in which the random DNA-binding property of the enzyme is converted to a promoter-specific recognition, and the polymerase is primed to initiate transcription.
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PMID:Specific binding of monomeric bacteriophage T3 and T7 RNA polymerases to their respective cognate promoters requires the initiating ribonucleoside triphosphate (GTP). 294 71

The regulatory region of the Escherichia coli cya gene was analyzed by using S1 nuclease mapping and in vitro transcription experiments. The cya gene was transcribed, both in vivo and in vitro, from one major promoter (P2) and two weak promoters (P1 and P1') that are located about 200 base pairs upstream of P2. The transcription from P2 was specifically inhibited by cAMP-CRP (cAMP receptor protein) in vitro. This regulatory mechanism was shown to be physiologically relevant through quantitative analyses of the cya mRNA in intact cells by S1 and dot blot assays. DNase I protection experiments revealed that cAMP-CRP binds to the cya DNA region between +11 and -20, in which a consensus CRP binding sequence is present. Moreover, it was found that cAMP-CRP alters the binding of RNA polymerase to the promoter region, thus inhibiting the transcription of the cya gene.
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PMID:Transcription of the Escherichia coli adenylate cyclase gene is negatively regulated by cAMP-cAMP receptor protein. 298 47

The preceding paper presents evidence for the co-transcriptional expression of the ileS and lsp genes in Escherichia coli. To identify the promoter for the ileS-lsp operon, we have determined the nucleotide sequence of an 1.8-kilobase DNA fragment between the rpsT and IleS genes. The sequence data have revealed an open reading frame, designated gene X, which encodes a polypeptide with 312 amino acid residues. Both in vivo and in vitro expressions of the x gene result in the synthesis of a soluble protein with an apparent Mr of 35,000. The x gene is transcribed in the same direction as that of the ileS-lsp operon and opposite to that of the upstream adjacent rpsT gene. No transcription termination sequence can be discerned in the intercistronic region between the x and ileS genes. DNase I footprinting experiment revealed a RNA polymerase binding site at 170-151 base pairs upstream of the x gene.
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PMID:Characterization of the ileS-lsp operon in Escherichia coli. Identification of an open reading frame upstream of the ileS gene and potential promoter(s) for the ileS-lsp operon. 298 4

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