Genetic inactivation of acrAB or inhibition of efflux induces expression of ramA.

OBJECTIVES: The transcriptional activator RamA regulates production of the multidrug resistance efflux AcrAB-TolC system in several Enterobacteriaceae. This study investigated factors that lead to increased expression of ramA. METHODS: In order to monitor changes in ramA expression, the promoter region of ramA was fused to a gfp gene encoding an unstable green fluorescence protein (GFP) on the reporter plasmid, pMW82. The ramA reporter plasmid was transformed into Salmonella Typhimurium SL1344 and a ΔacrB mutant. The response of the reporter to subinhibitory concentrations of antibiotics, dyes, biocides, psychotropic agents and efflux inhibitors was measured during growth over a 5 h time period. RESULTS: Our data revealed that the expression of ramA was increased in a ΔacrB mutant and also in the presence of the efflux inhibitors phenylalanine-arginine-ß-naphthylamide, carbonyl cyanide m-chlorophenylhydrazone and 1-(1-naphthylmethyl)-piperazine. The phenothiazines chlorpromazine and thioridazine also increased ramA expression, triggering the greatest increase in GFP expression. However, inducers of Escherichia coli marA and soxS and 12 of 17 tested antibiotic substrates of AcrAB-TolC did not induce ramA expression. CONCLUSIONS: This study shows that expression of ramA is not induced by most substrates of the AcrAB-TolC efflux system, but is increased by mutational inactivation of acrB or when efflux is inhibited.

Characterization of multiple promoters and transcript stability in the sacB-sacC gene cluster in Zymomonas mobilis.

In Zymomonas mobilis, the extracellular levansucrase (SacB) and extracellular sucrase (SacC) are involved in sucrose hydrolysis. Genes coding for these two enzymes (sacB and sacC) are arranged in a cluster in the genome and separated by a short intervening sequence. The level of sacC transcript was 12-fold higher than that of sacB transcript. On the other hand, transcript stability analysis in sucrose grown cultures revealed that the half-life of the sacB transcripts (153 s) was more than twofold higher than that of sacC transcript (66 s). The decay curves of sacB and sacC transcripts analyzed by the semi-quantitative RT-PCR correlated well with the decay curves of the respective enzyme activities. In the sacB promoter disruption mutant, Z. moblis BT2, the extracellular sucrase activity decreased from 2.6 to 2.0 U mg(-1) in sucrose medium due to the loss of SacB expression. The expression of sacC in the absence of the sacB promoter suggested that these two genes could be transcribed as different mRNAs. The promoter-lacZ fusion studies in Escherichia coli proved that the short intervening region acts as a strong promoter for the sacC gene.

The bacterial LexA transcriptional repressor.

Bacteria respond to DNA damage by mounting a coordinated cellular response, governed by the RecA and LexA proteins. In Escherichia coli, RecA stimulates cleavage of the LexA repressor, inducing more than 40 genes that comprise the SOS global regulatory network. The SOS response is widespread among bacteria and exhibits considerable variation in its composition and regulation. In some well-characterised pathogens, induction of the SOS response modulates the evolution and dissemination of drug resistance, as well as synthesis, secretion and dissemination of the virulence. In this review, we discuss the structure of LexA protein, particularly with respect to distinct conformations that enable repression of SOS genes via specific DNA binding or repressor cleavage during the response to DNA damage. These may provide new starting points in the battle against the emergence of bacterial pathogens and the spread of drug resistance among them.

Catecholaminergic neurons in medullary nuclei are among the post-synaptic targets of descending projections from infralimbic area 25 of the rat medial prefrontal cortex.

The infralimbic (IL) 'visceromotor' area of the rat medial prefrontal cortex projects to strategic subcortical nuclei involved in autonomic functions. Central among these targets are the nucleus tractus solitarius (NTS) and the rostral ventrolateral medulla (rVLM). By combining tract-tracing using the anterograde tracer biotinylated dextran amine (BDA) with immunolabeling for tyrosine hydroxylase (TH; an enzyme marker of catecholaminergic neurons), a limited proportion of BDA-labeled IL axonal boutons in the NTS and rVLM was found to be closely associated with TH immunopositive (+) target structures. Such structural appositions were mainly located proximally over the labeled dendritic arbors of identified TH+ neurons. Quantitative ultrastructural examination revealed that in NTS, TH+ dendritic shafts comprised 7.0% of the overall post-synaptic target population innervated by BDA-labeled IL boutons, whereas TH+ dendritic spines represented 1.25% of targets. In rVLM, TH+ shafts represented 9.0% and TH+ spines 2.5% of IL targets. Labeled IL boutons established exclusively asymmetric Gray Type 1 (presumed excitatory) synaptic junctions. The results indicate that subpopulations of catecholaminergic neurons in the NTS and rVLM are among the spectrum of post-synaptic neurons monosynaptically innervated by descending 'excitatory' input from IL cortex. Such connectivity, albeit restricted, identifies the potential direct influence of IL cortex on the processing and distribution of cardiovascular, respiratory and related autonomic information by catecholaminergic neurons in the NTS and VLM of the rat.

Recruitment of RNA polymerase to Class II CRP-dependent promoters is improved by a second upstream-bound CRP molecule.

Genetics and biochemistry have been exploited to investigate transcription activation by the Escherichia coli CRP (cAMP receptor protein) factor at promoters with a DNA site for CRP near position -41 and the effects of a second upstream-bound CRP molecule. We show that the upstream-bound CRP contributes to transcription activation by improving the recruitment of RNA polymerase.

Amygdala input monosynaptically innervates parvalbumin immunoreactive local circuit neurons in rat medial prefrontal cortex.

The projection from the basolateral nucleus of the amygdala (BLA) conveys information about the affective significance of sensory stimuli to the medial prefrontal cortex (mPFC). By using an anterograde tract-tracing procedure combined with immunocytochemistry and correlated light/electron microscopical examination, labeled BLA afferents to layers 2-6 of the rat mPFC are shown to establish asymmetrical synaptic contacts, not only with dendritic spines (approximately 95.7% of targets innervated), but also with the aspiny dendritic shafts and somata of multipolar parvalbumin immunopositive (PV+) neurons. A population of PV- dendritic shafts was also innervated. Labeled BLA synaptic input to identified PV+ structures occurred in layers 2-6 of mPFC. The results indicate that labeled BLA afferents predominantly contact the spiny processes of presumed pyramidal cells and also provide a direct and specific innervation to a sub-population of local circuit neurons in mPFC containing PV. Since PV+ cells include two significant classes of fast-spiking GABAergic inhibitory interneuron (basket and axo-axonic cells), these novel observations indicate that the amygdalocortical pathway in the rat has the ability to directly influence functionally strategic 'feed-forward' inhibitory mechanisms at the first stage of processing amygdalocortical information.

Disruption of the Zymomonas mobilis extracellular sucrase gene (sacC) improves levan production.

AIMS: Disruption of the extracellular Zymomonas mobilis sucrase gene (sacC) to improve levan production. METHODS AND RESULTS: A PCR-amplified tetracycline resistance cassette was inserted within the cloned sacC gene in pZS2811. The recombinant construct was transferred to Z. mobilis by electroporation. The Z. mobilis sacC gene, encoding an efficient extracellular sucrase, was inactivated. A sacC defective mutant of Z. mobilis, which resulted from homologous recombination, was selected and the sacC gene disruption was confirmed by PCR. Fermentation trials with this mutant were conducted, and levansucrase activity and levan production were measured. In sucrose medium, the sacC mutant strain produced threefold higher levansucrase (SacB) than the parent strain. This resulted in higher levels of levan production, whilst ethanol production was considerably decreased. CONCLUSIONS: Zymomonas mobilis sacC gene encoding an extracellular sucrase was inactivated by gene disruption. This sacC mutant strain produced higher level of levan in sucrose medium because of the improved levansucrase (SacB) than the parent strain. SIGNIFICANCE AND IMPACT OF THE STUDY: The Z. mobilis CT2, sacC mutant produces high level of levansucrase (SacB) and can be used for the production of levan.

A simple mechanism for co-dependence on two activators at an Escherichia coli promoter.

The Escherichia coli melAB promoter is co-dependent upon two transcription activators, MelR and the cyclic AMP receptor protein, CRP. In this study we demonstrate positive co-operativity between the binding of MelR and CRP at the melAB promoter, which provides a simple mechanism for its co-dependence. MelR binds to four sites, centred at positions -42.5, -62.5, -100.5 and -120.5 relative to the melAB transcription start point. When MelR is pre-bound, CRP is able to bind to a target located between MelR at positions -62.5 and -100.5. This increases the occupation of the two downstream sites for MelR, which is essential for transcription activation. We have identified residues within activating region 1 (AR1) of CRP that are important in transcription activation of the melAB promoter. At simple CRP-dependent promoters, the surface of CRP containing these residues is involved in contacting the RNA polymerase alpha subunit. Our results show that, at the melAB promoter, the surface of CRP containing AR1 contacts MelR rather than RNA polymerase. Thus, MelR and CRP activate transcription by a novel mechanism in which they bind co-operatively to adjacent sites and form a bacterial enhanceosome.

UP element-dependent transcription at the Escherichia coli rrnB P1 promoter: positional requirements and role of the RNA polymerase alpha subunit linker.

The UP element stimulates transcription from the rrnB P1 promoter through a direct interaction with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). We investigated the effect on transcription from rrnB P1 of varying both the location of the UP element and the length of the alpha subunit interdomain linker, separately and in combination. Displacement of the UP element by a single turn of the DNA helix resulted in a large decrease in transcription from rrnB P1, while displacement by half a turn or two turns totally abolished UP element-dependent transcription. Deletions of six or more amino acids from within the alpha subunit linker resulted in a decrease in UP element-dependent stimulation, which correlated with decreased binding of alphaCTD to the UP element. Increasing the alpha linker length was less deleterious to RNA polymerase function at rrnB P1 but did not compensate for the decrease in activation that resulted from displacing the UP element. Our results suggest that the location of the UP element at rrnB P1 is crucial to its function and that the natural length of the alpha subunit linker is optimal for utilisation of the UP element at this promoter.

A novel promoter architecture for microaerobic activation by the anaerobic transcription factor FNR.

The yfiD gene of Escherichia coli has an unusual promoter architecture in which an FNR dimer located at -93.5 inhibits transcription activation mediated by another FNR dimer bound at the typical class II position (-40.5). In vitro transcription from the yfiD promoter indicated that FNR alone can downregulate yfiD expression. Analysis of yfiD::lac reporters showed that five turns of the DNA helix between FNR sites was optimal for downregulation. FNR heterodimers, in which one subunit carried a defective repression surface, revealed that the upstream subunit of the -40.5 dimer and the downstream subunit of the -93.5 dimer were most important for downregulating yfiD expression. Deletion of the C-terminal domain of the alpha-subunit of RNA polymerase (RNAP) did not affect FNR-mediated repression, suggesting that repression is mediated through FNR-FNR and not FNR-RNAP interactions. Maximum yfiD::lac expression was observed in cultures exposed to 10 microM oxygen. More or less oxygen reduced expression dramatically. This pattern of response was dependent on the combination of a high-affinity site at the activating class II position and a lower affinity site at the upstream position.

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.

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.

Suppression of FNR-dependent transcription activation at the Escherichia coli nir promoter by Fis, IHF and H-NS: modulation of transcription initiation by a complex nucleo-protein assembly.

Expression from the Escherichia coli nir promoter is co-dependent on both the FNR protein (an anaerobically triggered transcription activator) and the NarL or NarP proteins (transcription activators triggered by nitrite and nitrate). Under anaerobic conditions, FNR binds to a site centred between positions -41 and -42, activating transcription of the nir operon. In previous work, we showed that this activation is suppressed by the binding of Fis protein, and at least one other protein, to sequence elements located upstream of the nir promoter. We proposed that the binding of NarL or NarP to a site centred between positions -69 and -70 counteracts this suppression, resulting in increased transcription in response to nitrite or nitrate. Here we have further investigated the different proteins that downregulate the nir promoter. We show that the nir promoter is repressed by three DNA binding proteins, Fis, IHF and H-NS. We demonstrate that, in addition to binding to its previously characterized upstream site located at position -142, Fis also binds to a second downstream site located at position +23. A second suppressing factor is IHF, that binds to a site located at position -88. Finally, the nucleoid associated protein, H-NS, preferentially binds to upstream sequences at the nir promoter and represses promoter activity. The association of Fis, IHF and H-NS suggests that nir promoter DNA is sequestrated into a highly ordered nucleo-protein structure that represses FNR-dependent transcription activation. NarL and NarP can relieve both IHF- and Fis-mediated repression, but are unable to counteract H-NS-mediated repression.

Regulation of acetyl coenzyme A synthetase in Escherichia coli.

Cells of Escherichia coli growing on sugars that result in catabolite repression or amino acids that feed into glycolysis undergo a metabolic switch associated with the production and utilization of acetate. As they divide exponentially, these cells excrete acetate via the phosphotransacetylase-acetate kinase pathway. As they begin the transition to stationary phase, they instead resorb acetate, activate it to acetyl coenzyme A (acetyl-CoA) by means of the enzyme acetyl-CoA synthetase (Acs) and utilize it to generate energy and biosynthetic components via the tricarboxylic acid cycle and the glyoxylate shunt, respectively. Here, we present evidence that this switch occurs primarily through the induction of acs and that the timing and magnitude of this induction depend, in part, on the direct action of the carbon regulator cyclic AMP receptor protein (CRP) and the oxygen regulator FNR. It also depends, probably indirectly, upon the glyoxylate shunt repressor IclR, its activator FadR, and many enzymes involved in acetate metabolism. On the basis of these results, we propose that cells induce acs, and thus their ability to assimilate acetate, in response to rising cyclic AMP levels, falling oxygen partial pressure, and the flux of carbon through acetate-associated pathways.

Transcription activation by the Escherichia coli cyclic AMP receptor protein: determinants within activating region 3.

At Class II CRP-dependent promoters, the Escherichia coli cyclic AMP receptor protein (CRP) activates transcription by making multiple interactions with RNA polymerase (RNAP). Two discrete surfaces of CRP, known as Activating Region 1 (AR1) and Activating Region 2 (AR2), interact with the C-terminal and N-terminal domains, respectively, of the alpha subunit of RNAP. Activating Region 3 (AR3) is a third separate surface of CRP, which is thought to interact with a target in the C-terminal region of the RNAP sigma(70) subunit. We have used a CRP mutant that functions primarily via AR3, CRP HL159 KE101 KN52, as a tool to identify residues within AR3 that are important for activation. This was achieved by screening a random mutant library of the gene encoding CRP HL159 KE101 KN52 for positive control mutants at Class II CRP-dependent promoters, and also by performing alanine scanning mutagenesis. Using both in vivo reporter assays and in vitro transcription assays, we measured the effects of key substitutions within AR3 on transcription activation in both CRP HL159 KE101 KN52 and wild-type CRP. We show that a cluster of negatively charged surface-exposed residues at positions 53, 54, 55 and 58 is required for optimal activation at a Class II, but not at a Class I, CRP-dependent promoter. We conclude that these residues in AR3 of CRP form an activatory determinant for Class II transcription activation. Abortive initiation assays were used to show that this activatory determinant accelerates the rate of isomerisation from the closed to open complex at a Class II CRP-dependent promoter. AR3 of CRP also contains an inhibitory determinant: the lysine residue at position 52 of CRP is inhibitory to maximal levels of transcription activation from Class II promoters. We show that the negative effects of K52 are not simply due to "masking" of the negatively charged residues at positions 53, 54, 55 and 58. Our results suggest that, during activation by wild-type CRP, the activatory and inhibitory determinants of AR3 balance each other. Thus, activation is predominantly determined by AR1 and AR2.

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.

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.

Role of activating region 1 of Escherichia coli FNR protein in transcription activation at class II promoters.

FNR is an Escherichia coli transcription factor that activates gene expression in response to anaerobiosis at a large number of promoters by making direct contacts with RNA polymerase. At class II FNR-dependent promoters, where the DNA site for FNR overlaps the -35 element, activating region 1 of FNR is proposed to interact with the C-terminal domain of the RNA polymerase alpha-subunit. Using a model class II FNR-dependent promoter, FF(-41.5), we have performed in vivo and in vitro experiments to investigate the role of this interaction. Our results show that FNR, carrying substitutions in activating region 1, is compromised in its ability to promote open complex formation and thus to activate transcription. Abortive initiation assays were used to assess the contribution of activating region 1 of FNR to open complex formation. A new method for the purification of the FNR protein is also described.

Transcription activation at the Escherichia coli melAB promoter: the role of MelR and the cyclic AMP receptor protein.

MelR is a melibiose-triggered transcription activator that belongs to the AraC family of transcription factors. Using purified Escherichia coli RNA polymerase and a cloned DNA fragment carrying the entire melibiose operon intergenic region, we have demonstrated in vitro open complex formation and activation of transcription initiation at the melAB promoter. This activation is dependent on MelR and melibiose. These studies also show that the cyclic AMP receptor protein (CRP) interacts with the melAB promoter and increases MelR-dependent transcription activation. DNAase I footprinting has been exploited to investigate the location of MelR-and CRP-binding sites at the melAB promoter. We showed previously that MelR binds to two identical 18 bp target sequences centred at position -100.5 (Site 1) and position -62.5 (Site 2). In this work, we show that MelR additionally binds to two other related 18 bp sequences: Site 1', centred at position -120.5, located immediately upstream of Site 1, and Site R, at position -238.5, which overlaps the transcription start site of the divergent melR promoter. MelR can bind to Site 1', Site 1, Site 2 and Site R, in both the absence and the presence of melibiose. However, in the presence of melibiose, MelR also binds to a fifth site (Site 2', centred at position -42.5) located immediately downstream of Site 2, and overlapping the -35 region of the melAB promoter. Additionally, although CRP is unable to bind to the melAB promoter in the absence of MelR, in the presence of MelR, it binds to a site located between MelR binding Site 1 and Site 2. Thus, tandem-bound MelR recruits CRP to the MelR. We propose that expression from the melAB promoter has an absolute requirement for MelR binding to Site 2'. Optimal expression of the melAB promoter requires Sites 1', Site 1, Site 2 and Site 2'; CRP acts as a 'bridge' between MelR bound at Sites 1' and 1 and at Sites 2 and 2', increasing expression from the melAB promoter. In support of this model, we show that improvement of the base sequence of Site 2' removes the requirement for Site 1' and Site 1, and short circuits the effects of CRP.

Repression of the Escherichia coli melR promoter by MelR: evidence that efficient repression requires the formation of a repression loop.

The Escherichia coli MelR protein is a transcription activator that, in the presence of melibiose, activates expression of the melAB operon by binding to four sites located just upstream of the melAB promoter. MelR is encoded by the melR gene, which is expressed from a divergent transcript that starts 237 bp upstream of the melAB promoter transcript start point. In a recent study, we have identified a fifth DNA site for MelR that overlaps the melR promoter transcript start and -10 region. Here we show that MelR binding to this site can downregulate expression from the melR promoter; thus, MelR autoregulates its own expression. Optimal repression of the melR promoter is observed in the absence of melibiose and requires one of the four other DNA sites for MelR at the melAB promoter. The two MelR binding sites required for this optimal repression are separated by 177 bp. We suggest that, in the absence of melibiose, MelR forms a loop between these two sites. We argue that, in the presence of melibiose, this loop is broken as the melAB promoter is activated. However, in the presence of melibiose, the melR promoter can still be partially repressed by MelR binding to the site that overlaps the transcript start and -10 region. Parallels with the Escherichia coli araC-araBAD regulatory region are discussed.

Mutations that increase the activity of the promoter of the Escherichia coli melibiose operon improve the binding of MelR, a transcription activator triggered by melibiose.

MelR is an Escherichia coli transcription factor that activates expression of the melAB operon in response to the presence of melibiose in the environment. MelR stimulates transcription initiation at the melAB promoter by binding to four sites centered at positions -120.5, -100.5, -62.5, and -42.5 upstream of the transcript start point. In a previous study, we described a spontaneous mutant that exhibited increased melAB expression. Sequence analysis showed that this mutant carries five consecutive base changes at positions -49, -50, -51, -52, and -53 upstream of the melAB transcript start. Here we show that these changes improve MelR binding to the target site centered at position -42.5 at the melAB promoter and that this improvement is responsible for increased promoter activity. Thus, the activity of the melAB promoter is fixed by the occupation by MelR of a DNA site that overlaps the -35 hexamer: MelR appears to be a typical class II-type transcription activator.

Positioning of region 4 of the Escherichia coli RNA polymerase sigma(70) subunit by a transcription activator.

A DNA cleavage reagent, specifically tethered to residue 581 of the Escherichia coli RNA polymerase sigma(70) subunit, has been used to investigate the location of sigma(70) region 4 in different complexes at the galp(1) promoter and the effect of the cyclic AMP receptor protein. The positions of DNA cleavage by the reagent are not affected by the cyclic AMP receptor protein. We conclude that transcription activation at the galp(1) promoter by the cyclic AMP receptor protein does not involve major conformation changes in or repositioning of sigma(70) region 4.