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)

Modeling the role of cyclic AMP (cAMP) in catabolite repression of inducible enzyme production in microbial cells was studied. A catabolite repression index, F, was defined based on the postulation that complex formation occurs between RNA polymerase (RNAP) and DNA, and shifting from the inert form to the open form of this complex (the latter form is required for transcription) is accelerated by the cAMP.CRP complex. The catabolite repression index, F, was incorporated into model equations of mRNA production. Empirical relationships between intracellular cAMP level and medium glucose concentration were established based on experimental data and introduced into the model. Computer simulation results were obtained for a number of interesting cases. The practical utility of the proposed model was demonstrated by comparing it with the experimental results on glucose isomerase biosynthesis.
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PMID:Modeling the role of cyclic AMP in catabolite repression of inducible enzyme biosynthesis in microbial cells. 21 39

Three temperature-sensitive mutant strains for RNA polymerase beta or beta' subunits (carrying mutations tsx, A2R7 and R120) were used in order to investigate the dependence of the induced lac expression on stimulation by cyclic AMP after the shift to non-permissive temperature. High temperature lowered the rate of beta-galactosidase synthesis. However, the low rate of synthesis could be strongly increased by cyclic AMP (30, 2.4 and 5.7-fold increases for tsX, A2R7 and R120 mutants, respectively). At the permissive temperature stimulation by cyclic AMP was less than 1.4-fold (minimal medium supplemented with glycerol). The results suggest that the maximal expression of the lac operon is saturated, that is, a hypothetical increase in RNA polymerase or cAMP-CRP concentration in the cell with not enhance the expression. The concept of saturation explains why it was possible to increase the beta-galactosidase synthesis in conditions of limited promoter binding activity of RNA polymerase through increase in concentration of cyclic AMP-CRP complex in the cell (addition of cyclic AMP) to the values higher than that observed on glycerol.
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PMID:Expression of the lac operon in RNA polymerase mutants of Escherichia coli K12. 22 41

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 cAMP-CRP complex activates the initiation of transcription at the Escherichia coli gal P1 promoter, and the activation efficiency is highly sensitive to the location of the complex on this promoter region. Moving the CRP binding site by one base pair toward the start of transcription significantly decreases the extent of activation in vivo and actually turns the cAMP-CRP complex into an inhibitor in in vitro experiments. A structural analysis of open complexes formed on the two promoter fragments at 37 degrees C has revealed three elements crucial for an optimal activation process: a strong upstream anchorage of RNA polymerase, a cooperative binding of CRP and RNA polymerase, and an accurate orientation of the two promoter regions located upstream and downstream of the CRP binding site. Furthermore, structural analysis of polymerase promoter complexes at lower temperatures suggests that RNA polymerase initially recognizes the upstream region of the gal P1 promoter and subsequently interacts with sequences from the -10 to +20 region to yield the final open complex structure. The involvement of CRP in these sequential events has been examined.
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PMID:Transcription activation by cAMP receptor protein (CRP) at the Escherichia coli gal P1 promoter. Crucial role for the spacing between the CRP binding site and the -10 region. 132 24

Singlet oxygen (1O2), generated by exciting an eosin-Tris complex with a high intensity beam of radiation at 532 nm, was used to chemically modify bases in fragments of DNA containing the lac UV5 promoter in the presence of the DNA binding proteins, RNA polymerase and CRP (cAMP receptor protein). Subsequent treatment with piperidine selectively cleaved the DNA at specific modified bases in the sequence. Using this technique we show first that the reactivity of DNA bound by CRP differs in the presence and absence of RNA polymerase. Hence the local conformation of CRP-bound DNA must change during the transition to the open complex. However, no reactivity is observed at the sites of the 40 degrees kinks described in the cocrystal structure (Steitz, 1990). Secondly we show that there is unique CRP-dependent reactivity at a specific site (position -46 on the upper strand) in the open complex. Finally, in the open complex, 1O2 also reacts with sites 90 bp upstream from the transcription start point. This reactivity is qualitatively CRP-independent. We infer that 1O2 reacts at sites where the promoter DNA is significantly distorted, and suggest that the pattern observed reflects the functional orientation of an active transcriptional complex in which the DNA is bent to form an extended loop.
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PMID:DNA deformation in nucleoprotein complexes between RNA polymerase, cAMP receptor protein and the lac UV5 promoter probed by singlet oxygen. 137 95

Escherichia coli integration host factor (IHF) binds with high affinity to two tandem IHF consensus sequences located upstream from the pL promoter of bacteriophage lambda. IHF was shown to stimulate transcription initiation from the pL promoter by increasing close complex formation (KB). We show here, by the use of reconstituted mutant RNA polymerases, that the C-terminal portion of the alpha subunit of RNA polymerase plays an essential role in the stimulation of transcription by IHF. Our results are in agreement with the hypothesis that IHF, like the cAMP-CRP activator, increases the affinity of RNA polymerase to the promoter by protein-protein interaction.
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PMID:Stimulation of the phage lambda pL promoter by integration host factor requires the carboxy terminus of the alpha-subunit of RNA polymerase. 143 3

The alpha subunit of Escherichia coli RNA polymerase plays a major role in the subunit assembly. Carboxyterminal deletion derivatives lacking 73 or 94 amino acid residues were assembled in vitro into enzyme molecules. Core enzymes consisting of these C-terminal-truncated alpha subunits were as active in RNA synthesis as native core enzyme. By the addition of sigma 70 subunit, these mutant enzymes initiated transcription from certain promoters. The mutant RNA polymerases, however, did not show cAMP-CRP activated transcription. These results demonstrate that the N-terminal region of the alpha subunit is involved in the formation of active enzyme molecule, while the C-terminal region plays an essential role in response to transcription activation by cAMP-CRP.
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PMID:Bipartite functional map of the E. coli RNA polymerase alpha subunit: involvement of the C-terminal region in transcription activation by cAMP-CRP. 164 77

CRP is resistant to attack by carboxypeptidase Y at 37 degrees C, whereas cAMP-CRP is digested yielding a core terminating at Thr-202 and lacking the seven carboxyl-terminal amino acid residues. A similar core (CRPCY) is formed when CRP is incubated with carboxypeptidase Y at 47 degrees C in the absence of cAMP. CRPCY has a more open conformation than CRP at 37 degrees C. While unliganded CRP is resistant to trypsin, CRPCY is sensitive to tryptic attack. Dithionitrobenzoic acid-mediated intersubunit disulfide crosslinking of CRP requires cAMP, CRPCY subunits are crosslinked in the absence of cAMP. The carboxyl-terminal region of unliganded CRP is conformationally restricted at 37 degrees C. The CRPCY retains cAMP binding activity. The CRPCY which terminates at Thr-202, no longer binds lac P+ DNA nor stimulates abortive initiation by RNA polymerase from the lac P+ promoter. The results indicate that the C-terminal region of CRP participates in the conformational stability of the closed form of CRP and indirectly in DNA binding by the open cAMP-CRP conformer.
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PMID:Characterization of the CRPCY core formed after treatment with carboxypeptidase Y. 165 82

The Escherichia coli rpoB636 mutant is defective in the transcription of lac and other catabolite-sensitive operons. The lac promoter variant, UV5, which is independent of cyclic AMP and the cyclic AMP receptor protein, CRP, was also defective in rpoB636 mutants. The activity of the lac UV5 promoter was restored to wild-type levels by deletion of cya (adenylate cyclase) or crp. Cyclic AMP and CRP apparently act as inhibitors of the rpoB636 RNA polymerase.
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PMID:An Escherichia coli rpoB mutation that inhibits transcription of catabolite-sensitive operons. 166 71

We have investigated a number of mutations that alter the ability of the E. coli transcription factors CRP and FNR to activate transcription. In CRP, some mutations at position 159 (H159L, H159I and delta 159) prevent transcription activation at a number of naturally-occurring and semi-synthetic CRP-dependent promoters. We suggest that some feature of the surface-exposed turn around residue 159 is recognised by RNA polymerase during transcription activation at these promoters. Mutations at position 52 increase CRP activity and reverse the effects of H159L and delta 159, most likely by creating a new contact with RNA polymerase. However this new contact only gives increased expression when the CRP binding site is located 41 1/2 base pairs upstream of the transcription start site and fails to reverse the effects of H159L and delta 159 at promoters where the CRP site is located further upstream. To explain our results we propose that the two surface-exposed turns around residues 52 and 159 contain elements that are potential RNA polymerase docking sites: in the CRP dimer these two active patches are located on adjacent faces of different subunits. FNR, a related transcription activator, contains amino acid sequences homologous to the CRP sequence around position 52. Mutations in this zone (from residues 81-88 in FNR) reduce expression from an FNR-dependent promoter without stopping FNR binding to its target. This defines a patch on FNR, which is homologous to the CRP surface-exposed loop around position 52, which is involved in transcription activation, most likely by contacting RNA polymerase.
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PMID:The role of two surface exposed loops in transcription activation by the Escherichia coli CRP and FNR proteins. 176 1

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