The TorR High-Affinity Binding Site Plays a Key Role in Both torR Autoregulation and torCAD Operon Expression in Escherichia coli

doi:10.1128/JB.182.4.961-966.2000

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Journal of Bacteriology, February 2000, p. 961-966, Vol. 182, No. 4
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

The TorR High-Affinity Binding Site Plays a Key Role in Both torR Autoregulation and torCAD Operon Expression in Escherichia coli

Mireille Ansaldi, Gwénola Simon, Michèle Lepelletier, and Vincent Méjean^*

Laboratoire de Chimie Bactérienne, Institut de Biologie Structurale et Microbiologie, Centre National de la Recherche Scientifique, 13402 Marseille Cedex 20, France

Received 9 August 1999/Accepted 24 November 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results and Discussion References

In the presence of trimethylamine N-oxide (TMAO), the TorS-TorR two-component regulatory system induces the torCAD operon,which encodes the TMAO respiratory system of Escherichia coli.The sensor protein TorS detects TMAO and transphosphorylates theresponse regulator TorR which, in turn, activates transcriptionof torCAD. The torR gene and the torCAD operon are divergentlytranscribed, and the short torR-torC intergenic region containsfour direct repeats (the tor boxes) which proved to be TorR bindingsites. The tor box 1-box 2 region covers the torR transcriptionstart site and constitutes a TorR high-affinity binding site,whereas box 3 and box 4 correspond to low-affinity binding sites.By using torR-lacZ operon fusions in different genetic backgrounds,we showed that the torR gene is negatively autoregulated. Surprisingly,TorR autoregulation is TMAO independent and still occurs in atorS mutant. In addition, this negative regulation involves onlythe TorR high-affinity binding site. Together, these data suggestthat phosphorylated as well as unphosphorylated TorR binds thebox 1-box 2 region in vivo, thus preventing RNA polymerase frombinding to the torR promoter whatever the growth conditions. Bychanging the spacing between box 2 and box 3, we demonstratedthat the DNA motifs of the high- and low-affinity binding sitesmust be close to each other and located on the same side of theDNA helix to allow induction of the torCAD operon. Thus, priorTorR binding to the box 1-box 2 region seems to allow cooperativebinding of phosphorylated TorR to box 3 and box4.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results and Discussion References

Trimethylamine N-oxide (TMAO) is an organic compound widespread in nature, and very high levels of it accumulate in the tissuesof fish, where it acts as a powerful osmoprotector (37). TMAOcan also play the role of an alternative electron acceptor forbacterial anaerobic respiration (2, 3). In Escherichia coli,the genes encoding the TMAO reductase respiratory system are clusteredin the torCAD operon (22). torC encodes a c-type cytochrome(TorC) anchored to the inner membrane, whereas torA encodes theperiplasmic terminal enzyme (TorA). TorD, the product of the thirdgene of the torCAD operon, seems to be a TorA chaperone (28).

Expression of the torCAD operon is under the control of both anaerobiosis and TMAO or related compounds (35). The TMAO controlis strict, as torCAD is rarely transcribed in the absence of TMAO(22). The anaerobic control is not as strong as that of TMAO,and expression of the tor operon decreases 5- to 10-fold underaerobic conditions (35). The tor anaerobic regulator, whichis different from FNR or ArcA, is still unknown, and the TMAOcontrol is mediated by the TorS-TorR two-component regulatorysystem (15, 35). We have shown that the sensor protein TorSseems to interact not only with TMAO but also with a periplasmicbinding protein, TorT (16) and with the immature form of theTorC cytochrome (1). Whereas TorT is a positive regulator essentialfor tor operon induction, the apoform of TorC plays a negativeautoregulatory role probably by inhibiting the TorS kinase activity.As TorS belongs to the family of the unorthodox sensors such asArcB or BvgS (7, 24), the signal transduction from TorS toTorR involves a four-step phosphorelay (14). Once phosphorylated,TorR activates the tor operon transcription by binding to thetorCAD promoter (34).

The short untranslated region between torR and torC contains four direct repeats of a decameric consensus motif (35) (seeFig. 2 and 3). These repeats have been called the tor boxes, andboxes 1, 2, and 4 correspond exactly to the same decameric sequence(CTGTTCATAT), whereas box 3 matches 7 of the 10 bases of the consensus(CCGTTCATCC). By using plasmid-born torC-lacZ transcriptionalfusions, we have observed that a double substitution within oneof the four tor boxes leads to a strong decrease in fusion activity(34). This clearly indicates that the tor boxes are importantcis elements involved in tor operon expression. We have furthershown that TorR binds specifically to the four tor boxes. However,we noticed from gel retardation assays and footprinting experimentsthat the box 1-box 2 region constitutes a high-affinity bindingsite for unphosphorylated TorR, whereas box 3 and box 4 are lower-affinitybinding sites (33, 34). In our working model, we proposedthat, first, a dimer of unphosphorylated TorR protein binds thebox 1-box 2 region. Under inducing conditions, TorR is transphosphorylatedand oligomerizes to form at least a tetramer. Then, two subunitsof the TorR tetramer interact with box 3 and box 4 leading tothe induction of tor operon expression. Alternatively, TorR~Pwould first weakly bind as a dimer to box 3 and box 4, and thiscomplex would then be stabilized by interaction with the TorRproteins previously bound to the box 1-box 2 site. In these models(34), we postulated that each TorR subunit binds one decamericdirect repeat in a cooperative manner. This hypothesis is probablycorrect as TorR belongs to the OmpR family of response regulators(17, 21, 27, 35), and members of this family have beenshown to bind cooperatively to multiple direct repeats (12,29, 30, 38). Moreover, it has been reported that an OmpRbinding site is comprised of two contiguous decameric repeats,more or less conserved, and that one OmpR molecule binds one DNArepeat (8, 9). The idea that emerges from several recentstudies is that DNA binding of members of the OmpR family requiresprotein-protein interactions and occurs in a hierarchical mannerso that high-affinity binding sites are filled first, and thisbinding facilitates interaction to weak binding sites by virtueof cooperativity (4, 10). Furthermore, phosphorylation ofthe response regulator seems to stimulate cooperative DNA binding(13).

As the TorR high-affinity binding site (box 1-box 2) covers the transcriptional start site of torR and overlaps its promoter $-$ 10 box (see Fig. 2), we decided to investigate whether or notthe torR gene is autoregulated. We found that torR is negativelyautoregulated and that full autoregulation requires an intactbox 1-box 2 region. In contrast, the lower-affinity binding sites,box 3 and box 4, seem to play no role in this autogenous regulation.More surprisingly, torR autoregulation is unaffected in a torSmutant. Therefore, TorR seems to repress torR expression by bindingthe box 1-box 2 region even when it is unphosphorylated. Together,these results are consistent with our model in which the high-affinitybinding site box 1-box 2 is bound by either the phosphorylatedor the unphosphorylated form of TorR (34). In this model, thebox 1-box 2 region plays the central role of a TorR oligomerizationsite, implying that the TorR binding site box 1-box 2 is properlypositioned relative to box 3 and box 4 in order to allow the formationof a specific nucleoprotein complex able to activate tor operontranscription in inducing conditions. The effects produced bychanging the spacing between box 2 and box 3 over the expressionof a torC-lacZ fusion confirmed our proposal and showed that themotifs of the four boxes must be on the same side of the DNA helix.In addition, the activity of the tor operon promoter is at a maximumwhen the high- and low-affinity binding sites are close to eachother.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results and Discussion References

Strains, plasmids, growth conditions, and general methods. All strains used in this study are derivatives of strain LCB506 (MC4100 pcnB). Strain LCB434 is a torS null mutant (14),and strain LCB507 was constructed by P1 transduction into strainLCB506 of a torR::mini-Tn10 allele (Cm^r), obtained by random mini-Tn10 mutagenesis (1). The mini-Tn10insertion site was determined by a rapid inverse PCR method aspreviously described (1), and it corresponds to position 583relative to the torR transcription start site. Bacteria were grownon L broth medium (23) in the presence of TMAO (10 mM) whereindicated. To maintain selection for plasmids or to select fortransductant strains, we used antibiotics as follows: ampicillin,50 µg · ml¹; chloramphenicol, 25 µg · ml¹; tetracycline, 25 µg · ml¹, and spectinomycin, 25 µg · ml¹. Anaerobic cultures were grown overnight without shaking at 37°Cin full-cap tubes. DNA preparations were carried out with thehigh pure DNA isolation kit from Boehringer Mannheim. PCR amplificationsand DNA restrictions were carried out using standard proceduresaccording to the supplier's instructions. Electrotransformationswere performed by the rapid method of Enderle and Farwell (5).

Primer extension analysis. Strain MC4100 was grown anaerobically to late exponential phase with or without TMAO (10 mM). Total RNA was prepared by thehot-phenol method (23), the quality of the sample was checkedelectrophoretically, and quantification was done by spectroscopy.The two synthetic oligonucleotides complementary to sequenceson the torR coding sequence (position 148 to 124 relative to thetorR transcription start site) and the torC coding sequence (position125 to 97 relative to the torCAD transcription start site) wereend labeled with [ $gamma$ -³²P]ATP using T4 polynucleotide kinase (U. S. Biochemicals) andwere coprecipitated with 20 µg of RNA. The same amount of primerand RNA was used in each experiment. The primer extension reactionwas performed with Moloney murine leukemia virus reverse transcriptaseas previously described (22, 35). A sequencing ladder wasproduced with a DNA template corresponding to the 5' torC regionand the oligonucleotide used for the primer extension of the torCmRNA.

Construction of plasmids. The plasmid series pPR was created by PCR amplification of the torR promoter sequence from position $-$ 124 to position +15 forplasmids pPR1 to pPR4 and from position $-$ 53 to position +15 forpPR5, relative to the torR transcription start site, using chromosomalDNA as a template. We used mutagenic primers carrying two pointmutations in box 1 (ATATGAACAG $right-arrow$ ATATGCATAG), box3 (GGATGAACGG $right-arrow$ GGATGCATGG), and box 4 (ATATGAACAG $right-arrow$ ATATGCATAG)for plasmids pPR2, pPR3, and pPR4, respectively. The PCR products,purified with Geneclean (BIO 101) and blunted using T4 DNA polymerase(Takara blunting kit), were then introduced into plasmid pGE593(6) previously linearized with SmaI, thus placing the lacZgene under the control of the torRpromoter.

The plasmid series pPTor was created with a similar strategy by PCR amplification of the torCAD promoter sequence (from position $-$ 86 to position +276 relative to the torCAD transcription startsite) and cloning into vector pGE593 (34). To create sequenceinsertions (pPTor28, -29, -32, and -33) or deletions (pPTor32and -36) between box 2 and box 3, we performed PCR with insertion-or deletion-containing primers which start from the same 5' extremity(see Fig. 3). Detailed information on the primer sequences isavailable from the authors onrequest.

All plasmids were checked by PCR with the upstream primer of the insert and a lacZ primer complementary to the lacZ sequenceof pGE593 (1). The sequences of the PCR products were verifiedby direct sequencing with the lacZprimer.

$beta$ -Galactosidase assays. $beta$ -Galactosidase activity was measured on whole cells by the method of Miller (23); the measures were repeated at least threetimes to confirm reproducibility, and the standard deviation wasno more than 15%.

	RESULTS AND DISCUSSION

Top Abstract Introduction Materials and Methods Results and Discussion References

Negative autoregulation of the torR gene. The torR gene and the torCAD operon are divergently transcribed, and their transcriptional start sites have been previouslydetermined by primer extension (22, 35) (for the positionof the transcription start sites see Fig. 2 and 3). From theseexperiments, we deduced that the torR and the torCAD promotersare back-to-back and so close that no intervening DNA sequenceis found between the two promoter $-$ 35 boxes. As torCAD is expressedonly in the presence of TMAO under anaerobic conditions, we wonderedwhether the torR gene was also regulated by TMAO. To answer thisquestion, we carried out the same primer extension experimentsas previously described, but RNA was prepared from cells growneither in the presence or absence of TMAO. As shown in Fig. 1,the level of torR transcription was almost the same in the presenceor absence of TMAO. In contrast and as expected, no transcriptionwas detected for the torCAD operon in the absence of TMAO, whereastor operon transcription was observed in the presence of inducer.

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FIG. 1. Primer extension analysis of torR and torCAD. The labeled primers were annealed to RNA from MC4100 cells grown anaerobically in the absence ( $-$ lanes) or presence (+ lanes) of 10 mM TMAO and extended with reverse transcriptase. Lanes A, C, G, and T are a sequencing ladder of the torC DNA region made with the same primer as that used in the primer extension reaction of torC.

To confirm that the torR promoter was constitutively expressed whatever the growth conditions, we constructed a hybrid plasmidin which the torR promoter region was fused to the lacZ codingsequence of the operon fusion vector pGE593. In this plasmid (pPR1),the tor DNA fragment carries the four tor boxes and extends fromposition $-$ 124 to position +15 relative to the torR transcriptionstart site (+1). To avoid any artifactual effect on fusion activitydue to the high copy number of the plasmid, we introduced pPR1and the other plasmids used in this study into pcnB strains. Becauseof the pcnB mutation, the copy number of the plasmid remains verylow in this type of strain (18). In a tor wild-type context,the torR-lacZ fusion from pPR1 was expressed at almost the samelow level in the presence or absence of TMAO under anaerobic conditions(Fig. 2). This result is consistent with the primer extensionanalysis described above and confirms that TMAO does not affecttorR expression. In addition, expression of the torR-lacZ fusionwas not significantly modified under aerobic growth conditions(data not shown). Therefore, in contrast to several response regulatorgenes (25, 36), the torR gene seems to be expressed at thesame low level whatever the growth conditions.

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FIG. 2. Activity of the torR promoter mutated or not mutated on tor boxes in different genetic backgrounds. (Left) The tor boxes are overlined, and the transcription start site of torR is indicated by a +1 arrow. Except for pPR5, the 5' part of the cloned tor sequence is not shown (as indicated by $-$ // $-$ ). The 5' end of the cloned tor fragment corresponds to position $-$ 124, relative to the torR transcription start site for pPR1 to pPR4 and to position $-$ 53 for pPR5; the 3' extremity of the cloned fragment for all pPR plasmids corresponds to position +15. For plasmids pPR2, pPR3, and pPR4, only the point mutations are indicated. (Right) The LCB506 (tor wild-type [wt]), LCB507 (torR), and LCB434 (torS) strains containing the pPR plasmids were grown anaerobically in the presence (+) or absence ( $-$ ) of TMAO. $beta$ -Galactosidase activity of the plasmid-borne torR-lacZ fusions is expressed in Miller units.

As the TorR response regulator mediates TMAO induction of the tor operon promoter, we thought at first that the torR genewas constitutively expressed regardless of TorR. To test thishypothesis, we introduced pPR1 into a torR strain. Surprisingly, $beta$ -galactosidase activity was five- to sixfold higher than thatmeasured in a torR⁺ strain (Fig. 2). This result strongly suggests that the torRgene is negatively autoregulated, but an apparent paradox is thatTorR autoregulation also takes place in the absence of TMAO (Fig.1 and 2). An attractive possibility is that TorR can downregulateits own gene expression even when it is unphosphorylated. To clarifythis last point, we decided to introduce pPR1 into a torS strain,since TorS transphosphorylates TorR in TMAO inducing conditions(14). As shown in Fig. 2, $beta$ -galactosidase activity measuredin the torS strain is low whatever the growth conditions, andit is equivalent to that observed in a tor wild-type strain. TorSis thus not required for the TorR autoregulatory process. Thisresult agrees with the fact that torR gene expression is unaffectedby TMAO availability and supports the idea that TorR acts as anegative autoregulator in its phosphorylated, as well as unphosphorylated,form. Alternatively, a small amount of phosphorylated TorR mightfulfil the autoregulatory function in the absence of TMAO, butthis is unlikely because TorS is the only known sensor partnerof TorR (1, 15).

TorR autoregulation requires only the high-affinity binding site. As the four tor boxes are necessary for torCAD operon induction and constitute TorR DNA-binding sites (34), we supposedthat the same cis-acting elements were implicated in TorR negativeautoregulation as well. To test this hypothesis, we separatelychanged the tor boxes 1, 3, and 4 by a double substitution aspreviously described (34). Indeed, substitutions at conservedpositions 6 and 8 of the decameric consensus sequence (AAC toCAT [Fig. 2]) in any one of the four boxes strongly decreasedthe activity of a torC-lacZ fusion under inducing conditions.In the present study, we decided not to mutate tor box 2 becausethe torR transcription start site is located within this box,and mutations close to this site might artificially affect thelevel of expression of the torR-lacZ fusion. Figure 2 shows thatthe double substitution within tor box 1 (pPR2) increased thetorR-lacZ fusion activity in the tor wild-type strain about fourfold.In contrast, expression of the torR promoter remained nearly unchangedwhen either box 3 (pPR3) or box 4 (pPR4) was mutated (Fig. 2).These results clearly indicate that tor box 3 and box 4 are notrequired for torR autoregulation, whereas box 1 is essential forthis process. Considering that the box 1-box 2 region constitutesa single TorR binding site (33, 34), our results stronglysuggest that this high-affinity binding site alone is responsiblefor torR negativeautoregulation.

As a control, we also introduced the plasmids pPR2, pPR3, and pPR4 into the torR and torS strains (Fig. 2). As expected, theactivity of the fusion was similar in both torS and tor wild-typestrains for a given plasmid. This confirms that TorS plays norole in torR autoregulation and, consequently, expression of thetorR promoter also increased in a torS strain when box 1 was mutated.In a torR context, activity originating from plasmids pPR2, pPR3,or pPR4 reached levels similar to that measured from pPR1, andthis activity was always higher in the torR strain than in theother two strains. Together, these results highlight the negativeaction of TorR on torR gene expression. The fact that activitywas higher in the torR strain even for the box 1-mutated torRpromoter (pPR2) (Fig. 2) indicates that the effect of the mutationsin box 1 is not as strong as that of torR inactivation. This isconsistent with previous findings that showed that a double mutationin either box 1 or box 2 did not entirely prevent TorR bindingto the box 1-box 2 region (33, 34). Thus, TorR might stillslightly downregulate its own expression by binding loosely tothe mutated box 1-box 2region.

To confirm that repression of the torR promoter only requires TorR binding to the box 1-box 2 region, we cloned a small DNAfragment carrying just the torR promoter from position $-$ 53 to+15 relative to the torR transcription start site into pGE593.As expected, expression from this fusion (pPR5) (Fig. 2) remainedalmost unchanged in a wild-type or torS context, whereas it increasedabout sixfold in a torR strain. Together, these results clearlyshow that TorR negative autoregulation does not require auxiliarysites in addition to the box 1-box 2 region. As the box 1-box2 TorR binding region overlaps the RNA polymerase binding regionof the torR promoter, the interaction of TorR with this regionmight prevent RNA polymerase binding to the torR promoter by asimple steric hindrance mechanism. This repression mechanism isprobable because most repressors act by limiting the access ofthe RNA polymerase to the promoter, and steric hindrance is oneof the classical mechanisms used by repressors to achieve theirfunction (26, 32).

TorR high- and low-affinity binding sites must be properly positioned to each other to allow tor operon induction. It is striking that the DNA motifs of the tor boxes are found on the same side of the DNA helix (Fig. 2). This observationis consistent with our previous proposal in which TorR binds firstas a dimer to the box 1-box 2 region in its unphosphorylated formand then interacts, under inducing conditions, with the weak bindingsites, boxes 3 and 4, owing to cooperative interactions stimulatedby phosphorylation (34). Formation of such an active nucleoproteincomplex requires that the four TorR subunits are located closeto each other on the same side of the DNA helix. A similar modelhas been recently proposed for regulation of ompF by OmpR (13),and activation of the pstS gene involves a DNA-PhoB complex thatresembles the proposed DNA-TorR complex (19). However, an 11-bpintervening sequence is found between the high- and low-affinitybinding sites in the case of the tor operon promoter. To examinethe role of this intervening sequence over tor operon expressionand to check that the TorR binding sites must be present on thesame side of the DNA helix, we decided to change the distancebetween box 2 and box3.

Figure 3 summarizes the effects of small insertions or deletions within the box 2-box 3 intervening region over a plasmid-bornetorC-lacZ fusion. When the intervening region was changed so thatthe box 1-box 2 and box 3-box 4 DNA motifs were positioned onopposite sides of the DNA helix (pPTor28, pPTor32, and pPTor36),expression of the torC-lacZ fusion was very low whatever the growthconditions. In contrast, when the box 1-box 2 and box 3-box 4DNA motifs were positioned on the same side of the DNA helix (pPTor29,pPTor33, and pPTor34), the fusion activity increased in the presenceof TMAO. These results show that the DNA motifs of the high- andlow-affinity binding sites must be positioned on the same faceof the DNA helix to allow tor operon induction. Therefore, theTorR subunits activate tor operon expression by binding to thesame side of the DNAhelix.

Although a proper phasing between the tor boxes seems to be essential for tor operon expression, the distance between thehigh- and low-affinity binding sites appears to play an importantrole in the strength of the tor operon promoter. Indeed, insertionof one (pPTor29) or two (pPTor33) additional helical turns betweenbox 2 and box 3 led to a strong decrease in torC-lacZ fusion activityunder inducing conditions (Fig. 3). Furthermore, deletion of thebox 2-box 3 intervening region (pPTor34) resulted in an even higherfusion activity than that of the wild-type promoter fusion. Fromthis experiment, we conclude that the closer the high- and low-affinitybinding sites are, the higher tor operon expression is. Finally,we introduced the same plasmids into a torR strain and, as expected,no activity above the background level was measured (Fig. 3).

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FIG. 3. Activity of the tor operon promoter with base pair deletions or insertions between box 2 and box 3. (Left) The tor boxes are overlined, the sequence insertions are in italics, and the transcription start site of torC is indicated by a +1 arrow. The 3' part of the cloned tor sequence is not shown (as indicated by $-$ // $-$ ). The 3' end of the cloned tor fragment corresponds to position +275. (Right) The LCB506 (tor wild-type [wt]) and LCB507 (torR) strains containing the pPTor plasmids were grown anaerobically in the presence (+) or absence ( $-$ ) of TMAO. $beta$ -Galactosidase activity of the plasmid-borne torC-lacZ fusions is expressed in Miller units. bp, the number of base pairs inserted (+) or deleted ( $-$ ) between box 2 and box 3; ND, not determined.

Concluding remarks. In the present study, we show that the TorR response regulator is not only an activator of the tor structural operon but alsoa repressor of its own gene expression (20, 32). The torRgene and the tor operon are divergently transcribed, and our dataindicate that the box 1-box 2 TorR high-affinity binding site,located within the torR-torC intergenic region, is absolutelyrequired for both repression of torR and activation of torCAD.The fact that binding of TorR to the weaker binding sites of box3 and box 4, which are essential for tor operon expression, doesnot enhance torR repression strongly suggests that in contrastto many repressors (26, 32) TorR does not need to bind auxiliarybinding sites to achieve full repression. In addition, TorR seemsto bind the box 1-box 2 region in vivo in its unphosphorylatedform, since torR negative autoregulation depends on neither theTorS sensor partner nor the presence of TMAO (Fig. 1 and 2). Accordingly,torR negative autoregulation is likely to maintain TorR concentrationat a low level whatever the growthconditions.

Although the box 2-box 3 intervening sequence is essential for torR gene expression, as it is located within the torR promoterand carries part of the torR promoter $-$ 10 box, this DNA regionproved to be dispensable not only for TMAO induction of the toroperon (Fig. 3) but also for the anaerobic control of the sameoperon (data not shown). However, tor operon induction requiresstrict spacing between the high- and low-affinity binding sites,so that the repeat sequences of the four tor boxes are orientedto the same face of the DNA helix. This further supports our previousmodel concerning the formation of an active nucleoprotein complexin which a TorR~P tetramer binds the four tor boxes simultaneouslyand probably bends the tor regulatory region (34).

To extend our model, we propose now that RNA polymerase binds the torR promoter on the same side as TorR. Therefore, repressionefficiency might depend mainly on the competition between TorRand the RNA polymerase for their overlapping binding sites. Ifthis is true, then transcription of the torR gene should occuronly in the absence of TorR binding, and as expression of thetorCAD operon is strictly TorR-dependent, transcription initiationsof torR and torCAD might be mutually exclusive. Additional experimentsare required to better understand this complex regulatory process.It also remains to be answered how TorR activates transcriptionof the tor operon and whether or not the RNA polymerase that bindsthe tor operon promoter is positioned on the same side as TorR(11, 31).

	ACKNOWLEDGMENTS

We thank C. Iobbi-Nivol, C. Jourlin-Castelli, and M. C. Pascal for helpful discussions. We are grateful to D. Cazeilles fortechnical assistance and to S. Wells for critical reading of themanuscript.

This work was supported by grants from the Centre National de la Recherche Scientifique, the Université de la Méditerranée,and the MENRT (Programme de Recherche Fondamentale en Microbiologieet Maladies Infectieuses et Parasitaires). M.A. was supportedby grants from the MENRT and from the Fondation pour la RechercheMédicale(FRM).

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratoire de Chimie Bactérienne, Institut de Biologie Structurale et Microbiologie,Centre National de la Recherche Scientifique, 31 Chemin JosephAiguier, BP71, 13402 Marseille Cedex 20, France. Phone: (33) 491 16 40 32. Fax: (33) 4 91 71 89 14. E-mail: mejean{at}ibsm.cnrs-mrs.fr.

Present address: Laboratoire de Microbiologie Générale et Moléculaire, UFR Sciences, Europol'Agro, 51687 Reims Cedex 2,France.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results and Discussion
References

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16. Jourlin, C., G. Simon, J. Pommier, M. Chippaux, and V. Méjean. 1996. The periplasmic TorT protein is required for trimethylamine N-oxide reductase gene induction in Escherichia coli. J. Bacteriol. 178:1219-1223[Abstract/Free Full Text].

17. Kondo, H., A. Nakagawa, J. Nishihira, Y. Nishimura, T. Mizuno, and I. Tanaka. 1997. Escherichia coli positive regulator OmpR has a large loop structure at the putative RNA polymerase interaction site. Nat. Struct. Biol. 4:28-31[CrossRef][Medline].

18. Lopilato, J., S. Bortner, and J. Beckwith. 1986. Mutations in a new chromosomal gene of Escherichia coli K-12, pcnB, reduce plasmid copy number of pBR322 and its derivatives. Mol. Gen. Genet. 205:285-290[CrossRef][Medline].

19. Makino, K., M. Amemura, T. Kawamoto, S. Kimura, H. Shinagawa, A. Nakata, and M. Suzuki. 1996. DNA binding of PhoB and its interaction with RNA polymerase. J. Mol. Biol. 259:15-26[CrossRef][Medline].

20. Maloy, S., and V. Stewart. 1993. Autogenous regulation of gene expression. J. Bacteriol. 175:307-316[Free Full Text].

21. Martinez-Hackert, E., and A. M. Stock. 1997. Structural relationships in the OmpR family of winged-helix transcription factors. J. Mol. Biol. 269:301-312[CrossRef][Medline].

22. Méjean, V., C. Iobbi-Nivol, M. Lepelletier, G. Giordano, M. Chippaux, and M. C. Pascal. 1994. TMAO anaerobic respiration in Escherichia coli: involvement of the tor operon. Mol. Microbiol. 11:1169-1179[Medline].

23. Miller, J. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

24. Mizuno, T. 1997. Compilation of all genes encoding two-component phosphotransfer signal transducers in the genome of Escherichia coli. DNA Res. 4:161-168[Abstract].

25. Mouncey, N. J., and S. Kaplan. 1998. Cascade regulation of dimethyl sulfoxide reductase (dor) gene expression in the facultative phototroph Rhodobacter sphaeroides 2.4.1T. J. Bacteriol. 180:2924-2930[Abstract/Free Full Text].

26. Müller-Hill, B. 1998. Some repressors of bacterial transcription. Curr. Opin. Microbiol. 1:145-151[CrossRef][Medline].

27. Parkinson, J. S., and E. C. Kofoid. 1992. Communication modules in bacterial signaling proteins. Annu. Rev. Genet. 26:71-112[CrossRef][Medline].

28. Pommier, J., V. Méjean, G. Giordano, and C. Iobbi-Nivol. 1998. TorD, a cytoplasmic chaperone that interacts with the unfolded trimethylamine N-oxide reductase enzyme (TorA) in Escherichia coli. J. Biol. Chem. 273:16615-16620[Abstract/Free Full Text].

29. Pratt, L. A., and T. J. Silhavy. 1995. Porin regulon of Escherichia coli, p. 105-127. In J. A. Hoch, and T. J. Silhavy (ed.), Two-component signal transduction. ASM Press, Washington, D.C.

30. Rampersaud, A., S. L. Harlocker, and M. Inouye. 1994. The OmpR protein of Escherichia coli binds to sites in the ompF promoter region in a hierarchical manner determined by its degree of phosphorylation. J. Biol. Chem. 269:12559-12566[Abstract/Free Full Text].

31. Rhodius, V. A., and S. J. Busby. 1998. Positive activation of gene expression. Curr. Opin. Microbiol. 1:152-159[CrossRef][Medline].

32. Rojo, F. 1999. Repression of transcription initiation in bacteria. J. Bacteriol. 181:2987-2991[Free Full Text].

33. Simon, G. 1996. Régulation de l'expression de la triméthylamine N-oxyde réductase chez Escherichia coli: étude du régulateur de réponse, TorR, et de son interaction avec la région promotrice de l'opéron torCAD. Ph.D. thesis. Université de la Méditerranée, Marseille, France.

34. Simon, G., C. Jourlin, M. Ansaldi, M. C. Pascal, M. Chippaux, and V. Méjean. 1995. Binding of the TorR regulator to cis-acting direct repeats activates tor operon expression. Mol. Microbiol. 17:971-980[CrossRef][Medline].

35. Simon, G., V. Méjean, C. Jourlin, M. Chippaux, and M. C. Pascal. 1994. The torR gene of Escherichia coli encodes a response regulator protein involved in the expression of the trimethylamine N-oxide reductase. J. Bacteriol. 176:5601-5606[Abstract/Free Full Text].

36. Soncini, F. C., E. G. Vescovi, and E. A. Groisman. 1995. Transcriptional autoregulation of the Salmonella typhimurium phoPQ operon. J. Bacteriol. 177:4364-4371[Abstract/Free Full Text].

37. Wang, A., and D. W. Bolen. 1997. A naturally occurring protective system in urea-rich cells: mechanism of osmolyte protection of proteins against urea denaturation. Biochemistry 36:9101-9108[CrossRef][Medline].

38. Wietzorrek, A., and M. Bibb. 1997. A novel family of proteins that regulates antibiotic production in streptomycetes appears to contain an OmpR-like DNA-binding fold. Mol. Microbiol. 25:1181-1184[CrossRef][Medline].

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1.	Ansaldi, M., C. Bordi, M. Lepelletier, and V. Méjean. 1999. TorC apocytochrome negatively autoregulates the trimethylamine N-oxide (TMAO) reductase operon in Escherichia coli. Mol. Microbiol. 33:284-295[CrossRef][Medline].
2.	Barrett, E. L., and H. S. Kwan. 1985. Bacterial reduction of trimethylamine oxide. Annu. Rev. Microbiol. 39:131-149[CrossRef][Medline].
3.	Dos Santos, J. P., C. Iobbi-Nivol, C. Couillault, G. Giordano, and V. Méjean. 1998. Molecular analysis of the trimethylamine N-oxide (TMAO) reductase respiratory system from a Shewanella species. J. Mol. Biol. 284:421-433[CrossRef][Medline].
4.	Eder, S., W. Liu, and F. M. Hulett. 1999. Mutational analysis of the phoD promoter in Bacillus subtilis: implications for PhoP binding and promoter activation of Pho regulon promoters. J. Bacteriol. 181:2017-2025[Abstract/Free Full Text].
5.	Enderle, P. J., and M. A. Farwell. 1998. Electroporation of freshly plated Escherichia coli and Pseudomonas aeruginosa cells. BioTechniques 25:954-958[Medline].
6.	Eraso, J. M., and G. M. Weinstock. 1992. Anaerobic control of colicin E1 production. J. Bacteriol. 174:5101-5109[Abstract/Free Full Text].
7.	Goudreau, P. N., and A. M. Stock. 1998. Signal tranduction in bacteria: molecular mechanisms of stimulus-response coupling. Curr. Opin. Microbiol. 2:160-169.
8.	Harlocker, S. L., L. Bergstrom, and M. Inouye. 1995. Tandem binding of six OmpR proteins to the ompF upstream regulatory sequence of Escherichia coli. J. Biol. Chem. 270:26849-26856[Abstract/Free Full Text].
9.	Harrison-McMonagle, P., N. Denissova, E. Martinez-Hackert, R. H. Ebright, and A. M. Stock. 1999. Orientation of OmpR monomers within an OmpR:DNA complex determined by DNA affinity cleaving. J. Mol. Biol. 285:555-566[CrossRef][Medline].
10.	Head, C. G., A. Tardy, and L. J. Kenney. 1998. Relative binding affinities of OmpR and OmpR-phosphate at the ompF and ompC regulatory sites. J. Mol. Biol. 281:857-870[CrossRef][Medline].
11.	Hochschild, A., and S. L. Dove. 1998. Protein-protein contacts that activate and repress prokaryotic transcription. Cell 92:597-600[CrossRef][Medline].
12.	Huang, K. J., and M. M. Igo. 1996. Identification of the bases in the ompF regulatory region, which interact with the transcription factor OmpR. J. Mol. Biol. 262:615-628[CrossRef][Medline].
13.	Huang, K. J., C. Y. Lan, and M. M. Igo. 1997. Phosphorylation stimulates the cooperative DNA-binding properties of the transcription factor OmpR. Proc. Natl. Acad. Sci. USA 94:2828-2832[Abstract/Free Full Text].
14.	Jourlin, C., M. Ansaldi, and V. Méjean. 1997. Transphosphorylation of the TorR response regulator requires the three phosphorylation sites of the TorS unorthodox sensor in Escherichia coli. J. Mol. Biol. 267:770-777[CrossRef][Medline].
15.	Jourlin, C., A. Bengrine, M. Chippaux, and V. Méjean. 1996. An unorthodox sensor protein (TorS) mediates the induction of the tor structural genes in response to trimethylamine N-oxide in Escherichia coli. Mol. Microbiol. 20:1297-1306[CrossRef][Medline].
16.	Jourlin, C., G. Simon, J. Pommier, M. Chippaux, and V. Méjean. 1996. The periplasmic TorT protein is required for trimethylamine N-oxide reductase gene induction in Escherichia coli. J. Bacteriol. 178:1219-1223[Abstract/Free Full Text].
17.	Kondo, H., A. Nakagawa, J. Nishihira, Y. Nishimura, T. Mizuno, and I. Tanaka. 1997. Escherichia coli positive regulator OmpR has a large loop structure at the putative RNA polymerase interaction site. Nat. Struct. Biol. 4:28-31[CrossRef][Medline].
18.	Lopilato, J., S. Bortner, and J. Beckwith. 1986. Mutations in a new chromosomal gene of Escherichia coli K-12, pcnB, reduce plasmid copy number of pBR322 and its derivatives. Mol. Gen. Genet. 205:285-290[CrossRef][Medline].
19.	Makino, K., M. Amemura, T. Kawamoto, S. Kimura, H. Shinagawa, A. Nakata, and M. Suzuki. 1996. DNA binding of PhoB and its interaction with RNA polymerase. J. Mol. Biol. 259:15-26[CrossRef][Medline].
20.	Maloy, S., and V. Stewart. 1993. Autogenous regulation of gene expression. J. Bacteriol. 175:307-316[Free Full Text].
21.	Martinez-Hackert, E., and A. M. Stock. 1997. Structural relationships in the OmpR family of winged-helix transcription factors. J. Mol. Biol. 269:301-312[CrossRef][Medline].
22.	Méjean, V., C. Iobbi-Nivol, M. Lepelletier, G. Giordano, M. Chippaux, and M. C. Pascal. 1994. TMAO anaerobic respiration in Escherichia coli: involvement of the tor operon. Mol. Microbiol. 11:1169-1179[Medline].
23.	Miller, J. 1972. Experiments in molecular genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
24.	Mizuno, T. 1997. Compilation of all genes encoding two-component phosphotransfer signal transducers in the genome of Escherichia coli. DNA Res. 4:161-168[Abstract].
25.	Mouncey, N. J., and S. Kaplan. 1998. Cascade regulation of dimethyl sulfoxide reductase (dor) gene expression in the facultative phototroph Rhodobacter sphaeroides 2.4.1T. J. Bacteriol. 180:2924-2930[Abstract/Free Full Text].
26.	Müller-Hill, B. 1998. Some repressors of bacterial transcription. Curr. Opin. Microbiol. 1:145-151[CrossRef][Medline].
27.	Parkinson, J. S., and E. C. Kofoid. 1992. Communication modules in bacterial signaling proteins. Annu. Rev. Genet. 26:71-112[CrossRef][Medline].
28.	Pommier, J., V. Méjean, G. Giordano, and C. Iobbi-Nivol. 1998. TorD, a cytoplasmic chaperone that interacts with the unfolded trimethylamine N-oxide reductase enzyme (TorA) in Escherichia coli. J. Biol. Chem. 273:16615-16620[Abstract/Free Full Text].
29.	Pratt, L. A., and T. J. Silhavy. 1995. Porin regulon of Escherichia coli, p. 105-127. In J. A. Hoch, and T. J. Silhavy (ed.), Two-component signal transduction. ASM Press, Washington, D.C.
30.	Rampersaud, A., S. L. Harlocker, and M. Inouye. 1994. The OmpR protein of Escherichia coli binds to sites in the ompF promoter region in a hierarchical manner determined by its degree of phosphorylation. J. Biol. Chem. 269:12559-12566[Abstract/Free Full Text].
31.	Rhodius, V. A., and S. J. Busby. 1998. Positive activation of gene expression. Curr. Opin. Microbiol. 1:152-159[CrossRef][Medline].
32.	Rojo, F. 1999. Repression of transcription initiation in bacteria. J. Bacteriol. 181:2987-2991[Free Full Text].
33.	Simon, G. 1996. Régulation de l'expression de la triméthylamine N-oxyde réductase chez Escherichia coli: étude du régulateur de réponse, TorR, et de son interaction avec la région promotrice de l'opéron torCAD. Ph.D. thesis. Université de la Méditerranée, Marseille, France.
34.	Simon, G., C. Jourlin, M. Ansaldi, M. C. Pascal, M. Chippaux, and V. Méjean. 1995. Binding of the TorR regulator to cis-acting direct repeats activates tor operon expression. Mol. Microbiol. 17:971-980[CrossRef][Medline].
35.	Simon, G., V. Méjean, C. Jourlin, M. Chippaux, and M. C. Pascal. 1994. The torR gene of Escherichia coli encodes a response regulator protein involved in the expression of the trimethylamine N-oxide reductase. J. Bacteriol. 176:5601-5606[Abstract/Free Full Text].
36.	Soncini, F. C., E. G. Vescovi, and E. A. Groisman. 1995. Transcriptional autoregulation of the Salmonella typhimurium phoPQ operon. J. Bacteriol. 177:4364-4371[Abstract/Free Full Text].
37.	Wang, A., and D. W. Bolen. 1997. A naturally occurring protective system in urea-rich cells: mechanism of osmolyte protection of proteins against urea denaturation. Biochemistry 36:9101-9108[CrossRef][Medline].
38.	Wietzorrek, A., and M. Bibb. 1997. A novel family of proteins that regulates antibiotic production in streptomycetes appears to contain an OmpR-like DNA-binding fold. Mol. Microbiol. 25:1181-1184[CrossRef][Medline].