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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)
Under various stress conditions, two sigma subunits of
RNA polymerase
, sigmaS and sigma70, coexist in Escherichia coli cells. In contrast to sigma70, sigmaS is subject to intricate regulation and coordinates an emergency reaction to stress as well as long term stress adaptation. In vivo, the two sigma factors clearly control different genes. Yet, they are structurally and functionally very similar and basically recognize the same promoter sequences. Recent data suggest that sigma factor specificity at stress-activated promoters is affected by the interplay of the two RNA polymeraseholoenzymes with additional regulatory factors, such as H-NS, Lrp,
CRP
, IHF or Fis, that differentially affect transcription initiation by sigmaS or sigma70 in a promoter-specific manner.
...
PMID:Interplay of global regulators and cell physiology in the general stress response of Escherichia coli. 1032 69
Erwinia chrysanthemi 3937 secretes an arsenal of pectinolytic enzymes including several pectate lyases encoded by the pel genes. We characterized a novel cluster of pectinolytic genes consisting of the three adjacent genes pehV, pehW and pehX, whose products have polygalacturonase activity. The high similarity between the three genes suggests that they result from duplication of an ancestral gene. The transcription of pehV, pehW and pehX is dependent on several environmental conditions. They are induced by pectin catabolic products and this induction results from inactivation of the KdgR repressor which controls almost all the steps of pectin catabolism. The presence of calcium ions strongly reduced the transcription of the three peh genes. Their expression was also affected by growth phase, osmolarity, oxygen limitation and nitrogen starvation. In addition, the pehX transcription is affected by catabolite repression and controlled by the activator protein
CRP
. PecS, which was initially isolated as a repressor of virulence factors, acts as an activator of the peh transcription. We showed that the three regulators KdgR, PecS and
CRP
act by direct interaction with the promoter regions of the peh genes. Analysis of simultaneous binding of KdgR, PecS,
CRP
and
RNA polymerase
indicated that the activator effect of PecS results from a competition between PecS and KdgR for the occupation of overlapping binding sites. Thus, to activate peh transcription, PecS behaves as an anti-repressor against KdgR.
...
PMID:Analysis of three clustered polygalacturonase genes in Erwinia chrysanthemi 3937 revealed an anti-repressor function for the PecS regulator. 1056 5
The flhD and flhC genes constitute the flagellar master operon whose products are required for expression of all the remaining flagellar operons in Salmonella typhimurium. Here we report the molecular structure and in vivo and in vitro expression of the flhD operon. Nucleotide sequence analysis revealed that the upstream region of this operon contains the consensus sequence for the cAMP-
CRP
binding site. Primer extension analysis demonstrated six possible transcription start sites for this operon. They include
CRP
-dependent and
CRP
-repressible transcription start sites. The
CRP
-dependent transcription start site is located 203 bp upstream of the initiation codon of the flhD gene and preceded by the consensus sequences of the -10 and -35 regions of the sigma 70-dependent promoter. The putative cAMP-
CRP
binding site is located centered 70 bp upstream of this start site. The
CRP
-repressible transcription start site is located within this putative cAMP-
CRP
binding site. These two start sites were confirmed by in vitro transcription experiments using sigma 70-
RNA polymerase
with or without cAMP-
CRP
.
...
PMID:Structure and transcriptional control of the flagellar master operon of Salmonella typhimurium. 1058 19
The carboxy-terminal domain of the alpha subunit of Escherichia coli
RNA polymerase
, which is connected with the core part of
RNA polymerase
through a long flexible linker, plays decisive roles in transcription activation by directly interacting with a large number of transcription factors and upstream (UP) element DNA. Here we constructed a set of mutant RNA polymerases, each containing a mutant alpha subunit with an altered interdomain linker. Deletion of three amino acids from the linker exhibited 50% inhibition of cAMP receptor protein- (CRP-) dependent lac P1 transcription. Deletion of six amino acids completely knocked out the activity. Insertion of three amino acids did not affect the activity, whereas 40-60% inhibition was observed after insertion of one, two, or four amino acids. Substitution of 10 consecutive glycine residues resulted in nearly 90% reduction of the
CRP
-dependent activity, whereas 50% activity was retained after substitution of 10 proline residues or a sequence expected to form a strong alpha-helix. Essentially the same results were obtained with UP element-dependent rrnB P1 transcription. These observations altogether suggest that (i) sufficient length of the interdomain linker is required for transcription activation mediated by the alpha carboxy-terminal domain, (ii) the linker is not totally unstructured but has structural and torsional preferences to facilitate positioning of the carboxy-terminal domain to a proper location for the interaction with
CRP
and UP element, and (iii)
CRP
-dependent activation and UP element-dependent activation share a common intermediary state in which the positioning of the alpha carboxy-terminal domain is of primary importance.
...
PMID:Structural requirements for the interdomain linker of alpha subunit of Escherichia coli RNA polymerase. 1082
The Escherichia coli rhaBAD operon encodes the enzymes for catabolism of the sugar L-rhamnose. Full rhaBAD activation requires the AraC family activator RhaS (bound to a site that overlaps the -35 region of the promoter) and the cyclic AMP receptor protein (
CRP
; bound immediately upstream of RhaS at -92.5). We tested alanine substitutions in activating regions (AR) 1 and 2 of
CRP
for their effect on rhaBAD activation. Some, but not all, of the substitutions in both AR1 and AR2 resulted in approximately twofold defects in expression from rhaBAD promoter fusions. We also expressed a derivative of the alpha subunit of
RNA polymerase
deleted for the entire C-terminal domain (alpha-Delta235) and assayed expression from rhaBAD promoter fusions. The greatest defect (54-fold) occurred at a truncated promoter where RhaS was the only activator, while the defect at the full-length promoter (RhaS plus
CRP
) was smaller (13-fold). Analysis of a plasmid library expressing alanine substitutions at every residue in the carboxyl-terminal domain of the alpha subunit (alpha-CTD) identified 15 residues (mostly in the DNA-binding determinant) that were important at both the full-length and truncated promoters. Only one substitution was defective at the full-length but not the truncated promoter, and this residue was located in the DNA-binding determinant. Six substitutions were defective only at the promoter activated by RhaS alone, and these may define a protein-contacting determinant on alpha-CTD. Overall, our results suggest that
CRP
interaction with alpha-CTD may not be required for rhaBAD activation; however, alpha-CTD does contribute to full activation, probably through interactions with DNA and possibly RhaS.
...
PMID:Roles of cyclic AMP receptor protein and the carboxyl-terminal domain of the alpha subunit in transcription activation of the Escherichia coli rhaBAD operon. 1085 86
The Escherichia coli cyclic AMP receptor protein,
CRP
, induces transcription at Class II
CRP
-dependent promoters by making three different activatory contacts with different surfaces of holo
RNA polymerase
. One contact surface of
CRP
, known as Activating Region 3 (AR3), is functional in the downstream subunit of the
CRP
dimer and is predicted to interact with region 4 of the RNAP sigma(70) subunit. We have previously shown that a mutant
CRP
derivative that activates transcription primarily via AR3,
CRP
HL159 KE101 KN52, requires the positively charged residues K593, K597 and R599 in sigma(70) for activation. Here, we have used the positive control substitution, EK58, to disrupt AR3-dependent activation by
CRP
HL159 KE101 KN52. We then screened random mutant libraries and an alanine scan library of sigma(70) for candidates that restore activation by
CRP
HL159 KE101 KN52 EK58. We found that changes at R596 and R599 in sigma(70) can restore activation by
CRP
HL159 KE101 KN52 EK58. This suggests that the side-chains of both R596 and R599 in sigma(70) clash with K58 in
CRP
. Maximal activation by
CRP
HL159 KE101 KN52 EK58 is achieved with the substitutions RE596 or RD596 in sigma(70). We propose that there are specific charge-charge interactions between E596 or D596 in sigma(70) and K58 in AR3. Thus, no increase in activation is observed in the presence of another positive control substitution, EG58 (
CRP
HL159 KE101 KN52 EG58). Similarly, both sigma(70) RE596 and sigma(70) RD596 can restore activation by
CRP
EK58 but not
CRP
EG58, and they both decrease activation by wild-type
CRP
. We suggest that E596 and D596 in sigma(70) can positively interact with K58 in AR3, thereby enhancing activation, but negatively interact with E58, thereby decreasing activation. The substitution, KA52 in AR3 increases Class II
CRP
-dependent activation by removing an inhibitory lysine residue. However, this increase is not observed in the presence of either sigma(70) RE596 or sigma(70) RD596. We conclude that the inhibitory side-chain, K52 in AR3, clashes with R596 in sigma(70). Finally, we show that the sigma(70) RE596 and RD596 substitutions affect
CRP
-dependent activation from Class II, but not Class I, promoters.
...
PMID:Interactions between activating region 3 of the Escherichia coli cyclic AMP receptor protein and region 4 of the RNA polymerase sigma(70) subunit: application of suppression genetics. 1086 Jul 40
The Escherichia coli proP P2 promoter, which directs the expression of an integral membrane transporter of proline, glycine betaine, and other osmoprotecting compounds, is induced upon entry into stationary phase to protect cells from osmotic shock. Transcription from the P2 promoter is completely dependent on RpoS (sigma(38)) and Fis. Fis activates transcription by binding to a site centered at -41, which overlaps the promoter, where it makes a specific contact with the C-terminal domain of the alpha subunit of
RNA polymerase
(alpha-CTD). We show here that Fis and cyclic AMP (cAMP) receptor protein (
CRP
)-cAMP collaborate to activate transcription synergistically in vitro. Coactivation both in vivo and in vitro is dependent on
CRP
binding to a site centered at -121.5, but
CRP
without Fis provides little activation. The contribution by
CRP
requires the correct helical phasing of the
CRP
site and a functional activation region 1 on
CRP
. We provide evidence that coactivation is achieved by Fis and
CRP
independently contacting each of the two alpha-CTDs. Efficient transcription in vitro requires that both activators must be preincubated with the DNA prior to addition of
RNA polymerase
.
...
PMID:Coactivation of the RpoS-dependent proP P2 promoter by fis and cyclic AMP receptor protein. 1089 25
Activating Region 1 of Escherichia coli FNR protein is proposed to interact directly with the C-terminal domain of the
RNA polymerase
alpha subunit (alphaCTD) during transcription activation at FNR-regulated promoters. Using an alphaCTD alanine scan mutant library, we have identified the residues of alphaCTD that are important for FNR-dependent transcription activation. Residues Asp-305, Gly-315, Arg-317, Leu-318 and Asp-319 are proposed to be the key residues in the contact site on alphaCTD for Activating Region 1 of FNR. In previous work, it had been shown that Activating Region 1 of FNR is a large surface-exposed patch and that the two crucial amino acid residues are Thr-118 and Ser-187. In this work, we have constructed Arg-118 FNR and Arg-187 FNR and shown that both FNR derivatives are defective in transcription activation. However, the activity of FNR carrying Arg-118 can be partially restored by substitutions of Lys-304 in alphaCTD. Similarly, the activity of FNR carrying Arg-187 can be partially restored by substitutions of Arg-317 or Leu-318 in alphaCTD. The specificity of the restoration suggests that, during transcription activation by FNR, the side-chain of residue 118 in Activating Region 1 of FNR is located close to Lys-304 and Asp-305 in alphaCTD. Similarly, the side-chain of residue 187 in Activating Region 1 of FNR is located close to Arg-317 and Leu-318 in alphaCTD. These results can be used to model the interface between Activating Region 1 of FNR and its contact target in alphaCTD, and permit comparison of this interface with the interface between Activating Region 1 of the related transcription activator,
CRP
and alphaCTD.
...
PMID:Analysis of interactions between Activating Region 1 of Escherichia coli FNR protein and the C-terminal domain of the RNA polymerase alpha subunit: use of alanine scanning and suppression genetics. 1097 22
Activation of the Escherichia coli malEp promoter relies on the formation of a higher order structure involving cooperative binding of MalT to promoter-proximal and promoter-distal sites as well as
CRP
binding to three sites located in between. MalT is the primary activator and one function of
CRP
is to facilitate cooperative binding of MalT to its cognate sites by bending the intervening DNA. It is shown here that
CRP
also participates directly in malEp activation. This function is carried out by the molecule of
CRP
bound to the
CRP
site centered at -139.5 (
CRP
site 3). This molecule of
CRP
recruits
RNA polymerase
by promoting the binding of the
RNA polymerase
alpha subunit C-terminal domain (alphaCTD) to DNA immediately downstream from
CRP
site 3, via a contact between alphaCTD and activating region I of
CRP
. The action of MalT and
CRP
at malEp hence provides the example of a novel and complex mechanism for transcriptional synergy in prokaryotes whereby one activator both helps the primary activator to form a productive complex with promoter DNA and interacts directly with
RNA polymerase
holoenzyme.
...
PMID:Synergistic transcription activation: a dual role for CRP in the activation of an Escherichia coli promoter depending on MalT and CRP. 1101 24
The transcriptional activator CooA from Rhodospirillum rubrum contains a six-coordinate protoheme that acts as a CO sensor in vivo. CO is a physiological effector of CooA and replaces one of the axial ligands of the ferrous heme to form the CO-bound CooA that is active as the transcriptional activator. Cys75 or His77 is coordinated to the ferric and ferrous hemes in CooA, respectively. The redox-controlled ligand exchange between Cys75 and His77 proceeds during the change in the redox state of the heme. The reduction and oxidation midpoint potentials of CooA have been determined to be -320 and -260 mV, respectively. The properties of a functional chimera derived from
CRP
and CooA suggest that CooA activates the transcription by a similar mechanism to that for
CRP
at Class II
CRP
-dependent promoters. Alanine-scanning mutagenesis has revealed that Arg24 and Arg53 of CooA, which will be concerned with the protein-protein interaction with
RNA polymerase
, are critical amino acid residues for the transcriptional activator activity of CooA, and that Lys26 and Asp94 modulate the activity of CooA.
...
PMID:CO sensing and regulation of gene expression by the transcriptional activator CooA. 1113 38
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