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)

This paper describes the binding interactions of Escherichia coli transcription factors sigma 70 and NusA with core RNA polymerase, both free in solution and as a part of the functional transcription complex. High pressure liquid chromatography gel filtration and fluorescence techniques have been used to monitor the binding of these factors to core polymerase in solution at salt concentrations roughly comparable to the in vivo environment (250 mM-KCl, 50 mM-potassium phosphate (pH 7.5]; under these conditions all the interacting species exist separately as protein monomers. We find that sigma 70 and NusA binds competitively to core polymerase with a 1:1 binding stoichiometry in this milieu, and that NusA does not bind to the polymerase holoenzyme. Association constants of approximately 2 x 10(9) and 1 x 10(7) M-1 have been measured for the sigma 70-core polymerase interaction and for the NusA-core polymerase interaction, respectively. These findings are consistent with the original formulation of the NusA-sigma 70 cycle put forward by Greenblatt & Li, and provide the basis for a further (and preliminary) quantitative examination of these same interactions within the transcription complex. We use a number of molecular biological techniques, together with data from the literature, to estimate these binding constants in various phases of the transcription cycle. In keeping with our results in solution, we find that the effective binding affinity of sigma 70 for core polymerase within the "open" promoter-polymerase complex is at least 500-fold greater than that of NusA. As the transcription complex moves from the initiation to the elongation phase these relative binding affinities are reversed; the average association constant of NusA for the core polymerase in the elongation complex remains practically the same as in free solution (approx. 3 x 10(7) M-1), while the affinity of sigma 70 for core polymerase in this complex drops to less than 5 x 10(5) M-1. These results are used to begin to define the basic conformational states and interaction potentials of core polymerase in the various stages of the transcription cycle.
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PMID:Escherichia coli sigma 70 and NusA proteins. I. Binding interactions with core RNA polymerase in solution and within the transcription complex. 185 61

Osmoregulated transcription from the proU promoter of Escherichia coli has been successfully reconstituted from purified components in a simple in vitro system consisting of plasmid DNA template, RNA polymerase, and nucleotides in the absence of any other protein factor. proU transcription is stimulated by addition of high concentrations of potassium glutamate, the ionic compound accumulated in vivo during hyperosmotic stress. Transcription from the nonosmoregulated promoters beta la, lac, and pepN is inhibited under the same conditions, demonstrating the specificity of potassium glutamate as an inducer of proU transcription. proU transcription requires a circular DNA template, but stable alterations in the degree of supercoiling are unnecessary for this potassium glutamate-dependent signaling. These results agree well with previous data obtained in an S-30 coupled transcription/translation system and suggest that physiological changes in the ionic composition of the intracellular millieu can regulate gene expression.
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PMID:Osmotic control of proU transcription is mediated through direct action of potassium glutamate on the transcription complex. 197 30

The kil loci (kilA, kilB, kilC, and kilE) of incompatibility group P (IncP), broad-host-range plasmid RK2 were originally detected by their potential lethality to Escherichia coli host cells. Expression of the kil determinants is controlled by different combinations of kor functions (korA, korB, korC, and korE). This system of regulated genes, known as the kil-kor regulon, includes trfA, which encodes the RK2 replication initiator. The functions of the kil loci are unknown, but their coregulation with an essential replication function suggests that they have a role in the maintenance or host range of RK2. In this study, we have determined the nucleotide sequence of a 3-kb segment of RK2 that encodes the entire kilA locus. The region encodes three genes, designated klaA, klaB, and klaC. The phage T7 RNA polymerase-dependent expression system was use to identify three polypeptide products. The estimated masses of klaA and klaB products were in reasonable agreement with the calculated molecular masses of 28,407 and 42,156 Da, respectively. The klaC product is calculated to be 32,380 Da, but the observed polypeptide exhibited an apparent mass of 28 kDa on sodium dodecyl sulfate-polyacrylamide gels. Mutants of klaC were used to confirm that initiation of translation of the observed product occurs at the first ATG in the klaC open reading frame. Hydrophobicity analysis indicated that the KlaA and KlaB polypeptides are likely to be soluble, whereas the KlaC polypeptide was predicted to have four potential membrane-spanning domains. The only recognizable promoter sequences in the kilA region were those of the kilA promoter located upstream of klaA and the promoter for the korA-korB operon located just downstream of a rho-independent terminatorlike sequence following klaC. The transcriptional start sites for these promoters were determined by primer extension. Using isogenic sets of plasmids with nonpolar mutations, we found that klaA, klaB, and klaC are each able to express a host-lethal (Kil+) phenotype in the absence of kor functions. Inactivation of the kilA promoter causes loss of the lethal phenotype, demonstrating that all three genes are expressed from the kilA promoter as a multicistronic operon. We investigated two other phenotypes that have been mapped to the kilA region of RK2 or the closely related IncP plasmids RP1 and RP4: inhibition of conjugal transfer of IncW plasmids (fwB) and resistance to potassium tellurite. The cloned kilA operon was found to express both phenotypes, even in the presence of korA and korB, whose functions are known to regulate the kilA promoter. In addition, mutant and complementation analyses showed that the kilA promoter and the products of all three kla genes are necessary for expression of both phenotypes. Therefore, host lethality, fertility inhibition, and tellurite resistance are all properties of the kilA operon. We discuss the possible role of the kilA operon for RK2.
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PMID:Structural, molecular, and genetic analysis of the kilA operon of broad-host-range plasmid RK2. 204 66

By use of techniques described recently for lac permease [Roepe, P.D., & Kaback, H.R. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6087], the melibiose permease from Escherichia coli, another polytopic integral plasma membrane protein, has been purified in a metastable soluble form after overexpression of the melB gene via the T7 RNA polymerase system. As demonstrated with lac permease, soluble melibiose permease is dissociated from the membrane with 5.0 M urea and appears to remain soluble in phosphate buffer at neutral pH after removal of urea by dialysis, although the protein aggregates in a time- and concentration-dependent fashion. Moreover, soluble melibiose permease behaves as a monomer during purification by size exclusion chromatography in the presence of urea. Circular dichroism of purified soluble melibiose permease reveals that the protein is highly helical in potassium phosphate buffer and that secondary structure is disrupted in 5.0 M urea. Finally, purified melibiose permease can be reconstituted into proteoliposomes, and the preparations catalyze membrane potential driven H+/melibiose or Na+/methyl 1-thio-beta,D-galactopyranoside symport. The results provide further support for the notion that hydrophobic transmembrane proteins may be able to assume a nondenatured conformation in aqueous solution and extend the implication that the approach described may represent a general method for rapid isolation and reconstitution of this class of membrane proteins.
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PMID:Isolation and functional reconstitution of soluble melibiose permease from Escherichia coli. 218 31

We have used potassium permanganate as a probe to detect DNA duplex unwinding in vitro, in open complexes between E. coli RNA polymerase and DNa fragments carrying the E. coli galactose operon regulatory region. This zone contains 3 overlapping promoters which specify transcription initiation at 3 distinct startpoints. We have used mutant gal derivatives carrying different single point mutations, each of which allows initiation from only one of the 3 start sites. This has allowed us to compare duplex unwinding in open complexes at the 3 different promoters, and to show that the extent of the unwinding is similar in each case. Further, the pattern of DNA modification by potassium permanganate suggests a model for discrimination between the upper and lower strands. Finally, we show that DNA modification by potassium permanganate at the gal promoters is the same in vivo as in vitro.
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PMID:Unwinding of duplex DNA during transcription initiation at the Escherichia coli galactose operon overlapping promoters. 219 43

Transcription initiation at the Escherichia coli galP1 promoter does not depend on specific nucleotide sequences in the -35 region. Footprint analysis of transcriptionally competent complexes between E. coli RNA polymerase and DNA fragments carrying galP1 shows that RNA polymerase protects sequences as far upstream as -55, whereas sequences around the -35 region are exposed. In contrast, with galP1 derivatives carrying -35 region sequences resembling the consensus, RNA polymerase protects bases as far as -45, and the -35 region is fully protected. Taken together, our data suggest that the overall architecture of RNA polymerase-promoter complexes can vary according to whether or not consensus -35 region sequences are present; in the absence of these sequences, open complex formation requires distortion of the promoter DNA. However, the unwinding of promoter DNA around the transcription start is not affected by the nature of the -35 region sequence. With a galP1 derivative carrying point mutations in the spacer region that greatly reduce promoter activity, the protection of bases by RNA polymerase around the -10 sequence and transcription start site is reduced. In contrast, protection of the region upstream of -25 is unaffected by the spacer mutations, although sequences from -46 to -54 become hypersensitive to attack by potassium permanganate, indicating severe distortion or kinking of this zone. We suggest that, with this galP1 derivative, RNA polymerase is blocked in a complex that is an intermediate on the path to open complex formation.
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PMID:The organization of open complexes between Escherichia coli RNA polymerase and DNA fragments carrying promoters either with or without consensus -35 region sequences. 220 41

We present a reproducible method for the preparation of nuclear extracts from the yeast Saccharomyces cerevisiae that support efficient RNA polymerase B (II)-dependent transcription. Extracts from both a crude nuclear fraction and Percoll-purified nuclei are highly active for site-specific initiation and transcription of a G-free cassette under the Adenovirus major late promoter. At optimal extract concentrations transcription is at least 5 times more efficient with the yeast extracts than with HeLa whole cell extracts. We show that the transcriptional activity is sensitive to alpha-amanitin and to depletion of factor(s) recognizing the TATA-box of the promoter. The in vitro reaction showed maximal activity after 45 min, was very sensitive to Cl-, but was not affected by high concentrations of potassium. We find that the efficiency of in vitro transcription in nuclear extracts is reproducibly high when spheroplasting is performed with a partially purified beta 1,3-glucanase (lyticase). Therefore a simplified method to isolate the lyticase from the supernatant of Oerskovia xanthineolytica is also presented.
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PMID:Preparation and characterization of yeast nuclear extracts for efficient RNA polymerase B (II)-dependent transcription in vitro. 226 63

Activation of transcription at the Klebsiella pneumoniae nifLA promoter requires the phosphorylated form of the positive control protein NTRC, together with RNA polymerase modified by the alternative sigma factor sigma 54. Dimethylsulphate and potassium permanganate were used as probes to analyse the interaction of NTRC and sigma 54-RNA polymerase with supercoiled nifLA promoter DNA in vitro. In contrast to the glnAp2 promoter, sigma 54 holoenzyme did not protect guanine residues in the nifLA promoter from methylation in the absence of the activator. We propose that NTRC stabilizes the interaction of sigma 54-RNA polymerase with the -24, -12 region, in addition to its role in catalysing open complex formation. Phosphorylated NTRC binds to two sites located greater than 100 nucleotides upstream of the -24, -12 region; it also induces hyper-methylation of a G residue at -23. Enhanced methylation at -23 is not co-operative with the binding of activator to the upstream sites and may account for the ability of NTRC, when present at high concentration, to activate transcription in the absence of the upstream binding sites. The insertion of spacer mutations at -86 indicates that transcriptional activation of the nifLA promoter at low NTRC concentrations is face-of-the-helix dependent, both in vivo and in vitro. We propose that correct positioning of activator molecules at the upstream binding sites stabilizes the interaction of sigma 54-RNA polymerase with the downstream region via the formation of a DNA loop.
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PMID:Transcriptional activation of the Klebsiella pneumoniae nifLA promoter by NTRC is face-of-the-helix dependent and the activator stabilizes the interaction of sigma 54-RNA polymerase with the promoter. 268 43

The reagent potassium permanganate is used to probe lac transcription complexes by primer extension-probing analysis. A series of strongly hyperreactive bands, corresponding to the known melted region, is observed when open complexes are formed in vitro. A nearly identical pattern occurs in vivo, the signal intensity of which increases when open complexes are trapped with rifampicin. Quantitative comparison of the signal intensity obtained under steady-state conditions with that obtained in the presence of rifampicin indicates that transcription from each of three lac promoter variants is limited in vivo principally by the slow rate of open complex formation. The slow-start lac L8:UV5 promoter is also limited somewhat by slow RNA chain initiation. Slightly different patterns of KMnO4 reactivity at each promoter variant in the absence of RNA polymerase in vitro suggest that DNA sequence dictates the ultimate pattern of melting, with the polymerase acting principally to stabilize the melted state specified by the DNA sequence.
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PMID:KMnO4 as a probe for lac promoter DNA melting and mechanism in vivo. 272 74

Although protein-nucleic acid interactions exhibit dramatic dependences on both ion concentration and type in vitro, large variations in intracellular ion concentrations can occur in Escherichia coli and other organisms without apparent effects on gene expression in vivo. E. coli accumulates K+ and glutamate as cytoplasmic osmolytes. The cytoplasmic K+ concentration in E. coli varies from less than 0.2 to greater than 0.9 m as a function of external osmolarity; corresponding cytoplasmic glutamate concentrations range from less than 0.03 to greater than 0.25 m. Only low levels of chloride occur in the cytoplasm of E. coli at all osmotic conditions. Since most in vitro studies have been performed in chloride salts, whereas glutamate is the more relevant physiological anion, we have measured the effects of the substitution of potassium glutamate (KGlu) for KCl on the kinetics and equilibria of a variety of site-specific protein-DNA interactions in vitro. Both the interaction of E. coli RNA polymerase with two phage lambda promoters and the interactions of various restriction enzymes with their DNA cleavage sites are enhanced by this substitution. Using the abortive initiation assay, we find a greater than 30-fold increase in the second-order rate constant for open complex formation at the lambda PR promoter and a 10-fold increase at the lambda PR' promoter, when KGlu is substituted for KCl. Replacement of KCl by KGlu does not affect the strong salt dependences of these interactions; increasing either KCl or KGlu concentrations decreases both reaction rates and extents. Substitution of glutamate for chloride does, however, shift the range of salt concentrations over which these interactions are observable to higher K+ concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Replacement of potassium chloride by potassium glutamate dramatically enhances protein-DNA interactions in vitro. 288 98

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