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)

Cyclic AMP (cAMP) and its receptor protein (CRP) have a dual role in the regulation of the two promoters that control the galactose (gal) operon of Escherichia coli. One promoter, P1, requires cAMP-CRP for activity; the other, P2, is inhibited by these factors. We have examined the interactions site of cAMP-CRP on gal DNA by using two types of protection experiments, involving DNase digestion and methylation by dimethyl sulfate. Our results indicate that cAMP-CRP binds to gal DNA in a segment located between 50 and 24 base pairs preceding the P1 start point for transcription. Although the location of the cAMP-CRP interaction site is clearly different in gal and lac DNA, comparison of the DNA sequences suggests a similar recognition sequence. The location of the cAMP . CRP-binding site in gal further suggests that protein-protein interactions between RNA polymerase and cAMP . CRP play an important role in transcription initiation at the gal and possibly other cAMP-dependent promoters.
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PMID:Interaction site of Escherichia coli cyclic AMP receptor protein on DNA of galactose operon promoters. 22 78

The chemical alkylating agent dimethyl sulfate can probe the interaction between Escherichia coli RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) and the purine bases of a promoter. This agent methylates the N7 position on guanine or the N3 position on adenine; the bound protein can either protect these positions or affect the reactivity to produce an enhanced methylation. The pattern of DNA residues in the lactose promoter protected from, or enhanced to, methylation by a specifically bound polymerase shows that the enzyme covers a region of at least 38 base pairs, stretching upstream from the origin of transcription. These protein-DNA contacts occur predominantly in the major groove of the DNA helix. Furthermore, this pattern of methylation shows that the polymerase unwinds the helix at the origin of transcription. The relationship between polymerase-DNA contacts defined by dimethyl sulfate and known features of promoter structure is discussed. To facilitate these experiments I have constructed a plasmid that permits a unique 5'-end labeling of each strand of a 95-base-pair fragment containing a lac operon promoter. This plasmid contains two copies of the lac promoter-operator region.
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PMID:Contacts between Escherichia coli RNA polymerase and a lac operon promoter. 36 74

In vivo dimethyl sulfate footprinting of the Bacillus subtilis glnRA regulatory region under repressing and derepressing conditions demonstrated that the GlnR protein, encoded by glnR, interacts with two sites situated within and adjacent to the glnRA promoter. One site, glnRAo1, between positions -40 and -60 relative to the start point of transcription, is a 21-bp symmetrical element that has been identified as essential for glnRA regulation (H. J. Schreier, C. A. Rostkowski, J. F. Nomellini, and K. D. Hirschi, J. Mol. Biol. 220:241-253, 1991). The second site, glnRAo2, is a quasisymmetrical element having partial homology to glnRAo1 and is located within the promoter between positions -17 and -37. The symmetry and extent of modifications observed for each site during repression and derepression indicated that GlnR interacts with the glnRA regulatory region by binding to both sites in approximately the same manner. Experiments using potassium permanganate to probe open complex formation by RNA polymerase demonstrated that transcriptional initiation is inhibited by GlnR. Furthermore, distortion of the DNA helix within glnRAo2 occurred upon GlnR binding. While glutamine synthetase, encoded by glnA, has been implicated in controlling glnRA expression, analyses with dimethyl sulfate and potassium permanganate ruled out a role for glutamine synthetase in directly influencing transcription by binding to operator and promoter regions. Our results suggested that inhibition of transcription from the glnRA promoter involves GlnR occupancy at both glnRAo1 and glnRAo2. In addition, modification of bases within the glnRAo2 operator indicated that control of glnRA expression under nitrogen-limiting (derepressing) conditions included the involvement of a factor(s) other than GlnR.
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PMID:Interaction of the Bacillus subtilis glnRA repressor with operator and promoter sequences in vivo. 134 63

Central to the genetic regulatory circuit that controls Bradyrhizobium japonicum nif and fix gene expression is the NifA protein. NifA activates transcription of several nif and fix genes and autoregulates its expression during symbiosis in soybean root nodules or in free-living microaerobic conditions. High O2 tensions result in the lack of nif expression, possibly by inactivation of NifA through oxidation of an essential metal cofactor. Several B. japonicum nif and fix promoters have upstream activator sequences (UAS) required for optimal activation. The UAS are located more than 100 bp from the -24/-12 promoter and have been proposed to be binding sites for NifA. We investigated the interaction of NifA with the nifD promoter region by using in vivo dimethyl sulfate footprinting. NifA-dependent protection from methylation of the two UAS of this promoter was detected. Footprinting experiments in the presence of rifampin showed that UAS-bound NifA led to the formation of an open nifD promoter-RNA polymerase sigma 54 complex. Shift to aerobic growth resulted in a rapid loss of protection of both the UAS and the promoter, indicating that the DNA-binding and the activation functions of NifA were controlled by the O2 status of the cell. After an almost complete inactivation by oxygen, the NifA protein began to degrade. Furthermore, metal deprivation also caused degradation of NifA. In this case, however, the rates of NifA inactivation and NifA degradation were not clearly distinguishable. The results are discussed in the light of a previously proposed model, according to which the oxidation state of a NifA-metal complex influences the conformation of NifA for both DNA-binding and positive control functions.
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PMID:Influence of oxygen on DNA binding, positive control, and stability of the Bradyrhizobium japonicum NifA regulatory protein. 204 67

Comparative structural and functional results on the valine and tyrosine accepting tRNA-like molecules from turnip yellow mosaic virus (TYMV) and brome mosaic virus (BMV), and the corresponding cognate yeast tRNAs are presented. Novel experiments on TYMV RNA include design of variant genes of the tRNA-like domain and their transcription in vitro by T7 RNA polymerase, analysis of their valylation catalyzed by yeast valyl-tRNA synthetase, and structural mapping with dimethyl sulfate and carbodiimide combined with graphical modelling. Particular emphasis is given to conformational effects affecting the valylation capacity of the TYMV tRNA-like molecule (e.g., the effect of the U43----C43 mutation). The contacts of the TYMV and BMV RNAs with valyl- and tyrosyl-tRNA synthetases are compared with the positions in the molecules affecting their aminoacylation capacities. Finally, the involvement of the putative valine and tyrosine anticodons in the tRNA-like valylation and tyrosylation reactions is discussed. While an anticodon-like sequence participates in the valine identity of TYMV RNA, this seems not to be the case for the tyrosine identity of BMV RNA despite the fact that the tyrosine anticodon has been shown to be involved in the tyrosylation of canonical tRNA.
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PMID:Search of essential parameters for the aminoacylation of viral tRNA-like molecules. Comparison with canonical transfer RNAs. 220 41

Myxococcus xanthus, a myxobacterium, contains a peculiar branched RNA-linked DNA called msDNA. Reverse transcriptase has been shown to be required for the production of msDNA. Existence of proteins that bind to one of the two msDNAs in M. xanthus, msDNA.Mx162, was examined by gel retardation assays. Total cell-free extract yielded two distinct retarded bands. Both bands were sensitive to treatment with proteinase K, indicating that there is a protein(s) that is able to bind to msDNA. Further, the formation of the bands was inhibited by the addition of nonradioactive msDNA but not by a large excess of poly(dA) in the presence of a 5000-fold excess of poly(dI.dC).poly(dI.dC). In vivo footprinting using dimethyl sulfate revealed that the deoxynucleotide stretch from 60 to 161 is protected. When a M. xanthus cell lysate was centrifuged in a 16-30% glycerol gradient, msDNA was found to sediment in two peaks: a major peak corresponding in size to 14 S, and a minor one at 5 S. These results indicate that msDNA.Mx162 exists as a complex with specific proteins in the cell.
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PMID:Myxococcus xanthus msDNA.Mx162 exists as a complex with proteins. 250 5

Expression of the ompF and ompC genes of Escherichia coli requires the OmpR protein for transcriptional activation. In vivo binding of the OmpR protein to the ompF and ompC promoter regions was observed using an in vivo dimethyl sulfate DNA footprinting technique. Two different sequence motifs were found to be protected by OmpR in both the ompF and ompC promoter regions. This technique was further used to localize the DNA-binding domain of OmpR to be within the C-terminal 117 amino acid residues. Binding of the C-terminal portion OmpR to the ompF and ompC promoter regions, however, did not result in activation of transcription. Our results, together with sequence homologies between OmpR and other regulatory proteins, suggests that OmpR has separable domain structures: the C-terminal portion for binding-specific DNA sequences and the N-terminal portion for interacting with RNA polymerase and/or other transcription factors.
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PMID:Identification of the DNA-binding domain of the OmpR protein required for transcriptional activation of the ompF and ompC genes of Escherichia coli by in vivo DNA footprinting. 265 4

In vitro transcription of templates containing deletion-substitution mutations has localized two essential promoter elements of the 5 S rRNA gene of Saccharomyces cerevisiae. A promoter element spanning the start site of transcription extends from -14 to +8, and a short internal control region (ICR) extends from +81 to +94. Changes in spacing between these elements by more than a few base pairs significantly reduce transcription. The site of RNA polymerase III transcription factor A (TFIIIA) binding, mapped by determination of the G residues that are protected from methylation on exposure of the TFIIIA.5 S DNA complex to dimethyl sulfate, is coincident with the ICR. Incorporation of TFIIIC into the TFIIIA.5 S rRNA gene complex protects additional G residues 5' and 3' of the ICR from methylation.
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PMID:Transcription of the 5 S rRNA gene of Saccharomyces cerevisiae requires a promoter element at +1 and a 14-base pair internal control region. 268 67

We have used diethyl pyrocarbonate (DEP), which carbethoxylates adenine bases, and dimethyl sulfate (DMS), which methylates guanine residues and single-stranded cytosines, to probe bases in open complexes between RNA polymerase and the lac UV5 promoter in vitro. We compared the kinetics of reactivity between bases in an open complex and those in a single-stranded 35-mer fragment corresponding to the lower template strand of lac UV5 in the region -25 to +10 relative to the transcription start site. We observed that cytosine and adenine residues in the 35-mer fragment reacted according to a second-order process with DMS and DEP, respectively, at sufficiently low concentrations of the reagents and that the degree of reactivity was base position independent. In an open complex in the absence of substrates, we observed reactivity with DEP in adenines from -12 to +4 as well as +21 on the template strand and methylation by dimethyl sulfate of cytosines -6, -4, -2, and -1. No hyperreactivity was observed on the nontemplate strand. The degree of reactivity of bases between -12 and +4 was position dependent, maximum reactivity being displayed by bases in the middle of the region. The reaction was first order within the range of reagent concentration investigated. It was confirmed that in the presence of ApA and UTP cytosine +5, as well as cytosines -6, -4, -2, and -1, in an open complex became reactive to DMS. With regard to DEP the extent of reactivity of the adenine at position +3 was increased markedly, adenine +4 was brought into the single-stranded region, and the overall reactivity of adenine -10 decreased.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Fine mapping of DNA single-stranded regions using base-specific chemical probes: study of an open complex formed between RNA polymerase and the lac UV5 promoter. 276 90

The structure of the final initiation complex between E. coli RNA polymerase (RNAP) and the bla promoter from the transposon TN3 has been probed by footprinting experiments and base accessibility to dimethyl sulfate at 37 degrees C. At RNAP/promoter molar ratios "standard" for these experiments (greater than or equal to 10), the contacts on bla extend from -100 to +20, i.e. a length exceeding twice the dimension of the RNAP major axis [33]. Since footprinting at about equimolar amounts of RNAP and bla extends to the usual (-55 to +20) promoter domain, it is very likely that at least two RNAP's participate in the complex observed at tenfold higher RNAP/bla ratios. Under the latter conditions, the extended footprint (-100 to +20) is observed above 30 degrees C, whereas at 15 degrees C, only the -55 to +20 promoter area is contacted. Furthermore, gel retardation experiments show the presence of two complexes of different migration rates. We have reported earlier [21] that at the "standard" RNAP/bla ratio, transcription initiation from the bla promoter is inhibited. The correlation of this inhibition with the postulated two RNAP/bla complex suggests a regulation of bla gene expression by RNAP availability controlled for instance by growth rate. These results can be correlated with those reported in [14, 15] for the tyrT promoter. Interestingly, both promoter share significant sequence homologies.
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PMID:Far upstream sequences of the bla promoter from TN3 are involved in complexation with E. coli RNA-polymerase. 283 26

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