Physical and functional analysis of the prokaryotic enhancer of the sigma 54-promoters of the TOL plasmid of Pseudomonas putida

Tracing explosives in soil with transcriptional regulators of Pseudomonas putida evolved for responding to nitrotoluenes

Although different biological approaches for detection of anti-personnel mines and other unexploded ordnance (UXO) have been entertained, none of them has been rigorously documented thus far in the scientific literature. The industrial 2,4,6 trinitrotoluene (TNT) habitually employed in the manufacturing of mines is at all times tainted with a small but significant proportion of the more volatile 2,4 dinitrotoluene (2,4 DNT) and other nitroaromatic compounds. By using mutation-prone PCR and DNA sequence shuffling we have evolved in vitro and selected in vivo variants of the effector recognition domain of the toluene-responsive XylR regulator of the soil bacterium Pseudomonas putida that responds to mono-, bi- and trinitro substituted toluenes. Re-introduction of such variants in P. putida settled the transcriptional activity of the cognate promoters (Po and Pu) as a function of the presence of nitrotoluenes in the medium. When strains bearing transcriptional fusions to reporters with an optical output (luxAB, GFP) were spread on soil spotted with nitrotoluenes, the signal triggered by promoter activation allowed localization of the target compounds on the soil surface. Our data provide a proof of concept that non-natural transcription factors evolved to respond to nitroaromatics can be engineered in soil bacteria and inoculated on a target site to pinpoint the presence of explosives. This approach thus opens new ways to tackle this gigantic humanitarian problem.

Transcriptional wiring of the TOL plasmid regulatory network to its host involves the submission of the sigma54-promoter Pu to the response regulator PprA

Implantation of the regulatory circuit of the degradation pathway of TOL plasmid pWW0 in the native transcriptional network of the host Pseudomonas putida involves interplay between plasmid- and chromosome-encoded factors. We have employed a reverse genetics approach to investigate such a molecular wiring by identifying host proteins that form stable complexes with Pu, the sigma(54)-dependent promoter of the upper TOL operon of pWW0. This approach revealed that the Pu upstream activating sequences (UAS), the target sites of the cognate activator XylR, form a specific complex with a host protein which, following DNA affinity purification and mass spectrometry analysis, was identified as the LytTR-type two-component response regulator PprA. Directed inactivation of pprA resulted in the upregulation of the Pu promoter in vivo, while expression of the same gene from a plasmid vector strongly repressed Pu activity. Such a downregulation of Pu by PprA could be faithfully reproduced both in vitro with purified components and in an in vivo reporter system assembled in Escherichia coli. The overlap of the PprA and XylR binding sites suggested that the basis for the inhibitory effect on Pu was a mutual exclusion mechanism between the two proteins to bind the UAS. We argue that the binding of the response regulator PprA to Pu (a case without precedents in sigma(54)-dependent transcription) helps to anchor the TOL regulatory subnetwork to the wider context of the host transcriptome, thereby allowing the entry of physiological signals that modulate the outcome of promoter activity.

sigma54-promoter discrimination and regulation by ppGpp and DksA

The sigma(54)-factor controls expression of a variety of genes in response to environmental cues. Much previous work has implicated the nucleotide alarmone ppGpp and its co-factor DksA in control of sigma(54)-dependent transcription in the gut commensal Escherichia coli, which has evolved to live under very different environmental conditions than Pseudomonas putida. Here we compared ppGpp/DksA mediated control of sigma(54)-dependent transcription in these two organisms. Our in vivo experiments employed P. putida mutants and manipulations of factors implicated in ppGpp/DksA mediated control of sigma(54)-dependent transcription in combination with a series of sigma(54)-promoters with graded affinities for sigma(54)-RNA polymerase. For in vitro analysis we used a P. putida-based reconstituted sigma(54)-transcription assay system in conjunction with DNA-binding plasmon resonance analysis of native and heterologous sigma(54)-RNA polymerase holoenzymes. In comparison with E. coli, ppGpp/DksA responsive sigma(54)-transcription in the environmentally adaptable P. putida was found to be more robust under low energy conditions that occur upon nutrient depletion. The mechanism behind this difference can be traced to reduced promoter discrimination of low affinity sigma(54)-promoters that is conferred by the strong DNA binding properties of the P. putida sigma(54)-RNA polymerase holoenzyme.

Transcriptional regulation of the sulfate-starvation-induced gene sfnA by a sigma54-dependent activator of Pseudomonas putida

The sigma(54)-dependent transcriptional regulator SfnR is essential for the use of dimethyl sulfone (DMSO(2)) as a sulfur source by Pseudomonas putida DS1. SfnR binds three SfnR-binding sites (sites 1, 2 and 3) within an intergenic region of the divergently transcribed sfnAB and sfnFG gene clusters. The site 1 region, proximal to the sfnF gene, is indispensable for the expression of the sfnFG operon, which encodes components of DMSO(2) monooxygenase. We investigated the transcriptional regulation of the sfnAB operon and possible functions of the sfnA gene. RT-PCR analysis revealed that the sfnAB gene cluster, which is similar to homologues of the acyl-CoA dehydrogenase family, was transcribed as an operon, and its expression was regulated by SfnR under conditions of sulfate starvation. Deletion analyses using lacZ as a reporter demonstrated that the region up to at least -138 bp from the transcription start point of sfnA (containing sites 2 and 3) was necessary for the expression of the sfnAB operon. A growth test of the sfnA-disrupted mutant revealed the possibility that sfnA may be involved in the use of methanethiol as a sulfur source.

The upstream-activating sequences of the sigma54 promoter Pu of Pseudomonas putida filter transcription readthrough from upstream genes

Although the m-xylene-responsive sigma54 promoter Pu of Pseudomonas putida mt-2, borne by the TOL plasmid pWWO, is one of the strongest known promoters in vivo, its base-line level in the absence of its aromatic inducer is below the limit of any detection procedure. This is unusual because regulatory networks (such as the one to which Pu belongs) can hardly escape the noise caused by intrinsic fluctuations in background transcription, including that transmitted from upstream promoters. This study provides genetic evidence that the upstream-activating sequences (UAS), which serve as the binding sites for the pWW0-encoded XylR protein (the m-xylene-responsive sigma54-dependent activator of Pu), isolate expression of the upper TOL genes from any adventitious transcriptional flow originating further upstream. An in vivo test system was developed in which different segments of the Pu promoter were examined for the inhibition of incoming transcription products from an upstream promoter in P. putida and Escherichia coli. Minimal transcription filter ability was located within a 105-bp fragment encompassing the UAS of Pu. Although S1 nuclease assays showed that the UAS prevented the buildup of downstream transcripts, the mechanism seems to diverge from a typical termination system. This was shown by the fact that the UAS did not halt transcription in vitro and that the filter effect could not be relieved by the anti-termination system of lambda phage. Because the Pu promoter lies adjacent to the edge of a transposon in pWW0, the preset transcriptional filter in the UAS may isolate the upper TOL operon from undue expression after random insertion of the mobile genetic element in a new replicon.

The sigma54-dependent transcriptional activator SfnR regulates the expression of the Pseudomonas putida sfnFG operon responsible for dimethyl sulphone utilization

Pseudomonas putida DS1 is able to utilize dimethyl sulphide through dimethyl sulphoxide, dimethyl sulphone (DMSO2), methanesulphonate (MSA) and sulphite as a sulphur source. We previously demonstrated that sfnR encoding a sigma54-dependent transcriptional regulator is essential for DMSO2 utilization by P. putida DS1. To identify the target genes of SfnR, we carried out transposon mutagenesis on an sfnR disruptant (DMSO2-utilization-defective phenotype) using mini-Tn5, which contains two outward-facing constitutively active promoters; as a result, we obtained a mutant that restored the ability to utilize DMSO2. The DMSO2-positive mutant carried a mini-Tn5 insertion in the intergenic region between two opposite-facing operons, sfnAB and sfnFG. Both sfnA and sfnB products were similar to acyl-CoA dehydrogenase family proteins, whereas sfnF and sfnG encoded a putative NADH-dependent FMN reductase (SfnF) and an FMNH2-dependent monooxygenase (SfnG). Disruption and complementation of the sfn genes indicated that the sfnG product is essential for DMSO2 utilization by P. putida DS1. Furthermore, an enzyme assay demonstrated that SfnG is an FMNH2-dependent DMSO2 monooxygenase that converts DMSO2 to MSA. It was revealed that the expression of the sfnFG operon is directly activated by the binding of SfnR at its upstream region. Site-directed mutagenesis of the SfnR binding sequences allowed us to define a potential recognition sequence for SfnR. These results provided insight into regulation of sulphate starvation-induced genes in bacteria.

Characterization of HbpR binding by site-directed mutagenesis of its DNA-binding site and by deletion of the effector domain

In the presence of 2-hydroxybiphenyl, the enhancer binding protein, HbpR, activates the sigma54-dependent P(hbpC) promoter and controls the initial steps of 2-hydroxybiphenyl degradation in Pseudomonas azelaica. In the activation process, an oligomeric HbpR complex of unknown subunit composition binds to an operator region containing two imperfect palindromic sequences. Here, the HbpR-DNA binding interactions were investigated by site-directed mutagenesis of the operator region and by DNA-binding assays using purified HbpR. Mutations that disrupted the twofold symmetry in the palindromes did not affect the binding affinity of HbpR, but various mutations along a 60 bp region, and also outside the direct palindromic sequences, decreased the binding affinity. Footprints of HbpR on mutant operator fragments showed that a partial loss of binding contacts occurs, suggesting that the binding of one HbpR 'protomer' in the oligomeric complex is impaired whilst leaving the other contacts intact. An HbpR variant, devoid of its N-terminal sensing A-domain, was unable to activate transcription from the hbpC promoter while maintaining protection of the operator DNA in footprints. Wild-type HbpR was unable to activate transcription from the hbpC promoter when delta A-HbpR was expressed in the same cell, suggesting the formation of (repressing) hetero-oligomers. This model implies that HbpR can self-associate on its operator DNA without effector recognition or ATP binding. Furthermore, our findings suggest that the N-terminal sensing domain of HbpR is needed to activate the central ATPase domain rather than to repress a constitutively active C domain, as is the case for the related regulatory protein XylR.

Design of new promoters and of a dual-bioreporter based on cross-activation by the two regulatory proteins XylR and HbpR

The HbpR protein is the sigma54-dependent transcription activator for 2-hydroxybiphenyl degradation in Pseudomonas azelaica. The ability of HbpR and XylR, which share 35% amino acid sequence identity, to cross-activate the PhbpC and Pu promoters was investigated by determining HbpR- or XylR-mediated luciferase expression and by DNA binding assays. XylR measurably activated the PhbpC promoter in the presence of the effector m-xylene, both in Escherichia coli and Pseudomonas putida. HbpR weakly stimulated the Pu promoter in E. coli but not in P. azelaica. Poor HbpR-dependent activation from Pu was caused by a weak binding to the operator region. To create promoters efficiently activated by both regulators, the HbpR binding sites on PhbpC were gradually changed into the XylR binding sites of Pu by site-directed mutagenesis. Inducible luciferase expression from mutated promoters was tested in E. coli on a two plasmid system, and from mono copy gene fusions in P. azelaica and P. putida. Some mutants were efficiently activated by both HbpR and XylR, showing that promoters can be created which are permissive for both regulators. Others achieved a higher XylR-dependent transcription than from Pu itself. Mutants were also obtained which displayed a tenfold lower uninduced expression level by HbpR than the wild-type PhbpC, while keeping the same maximal induction level. On the basis of these results, a dual-responsive bioreporter strain of P. azelaica was created, containing both XylR and HbpR, and activating luciferase expression from the same single promoter independently with m-xylene and 2-hydroxybiphenyl.

TouR-mediated effector-independent growth phase-dependent activation of the sigma54 Ptou promoter of Pseudomonas stutzeri OX1

Transcription of the catabolic touABCDEF operon, encoding the toluene-o-xylene monooxygenase of Pseudomonas stutzeri OX1, is driven by the sigma(54)-dependent Ptou promoter, whose activity is controlled by the phenol-responsive NtrC-like activator TouR. In this paper we describe for the first time a peculiar characteristic of this system, namely, that Ptou transcription is activated in a growth phase-dependent manner in the absence of genuine effectors of the cognate TouR regulator. This phenomenon, which we named gratuitous activation, was observed in the native strain P. stutzeri OX1, as well as in a Pseudomonas putida PaW340 host harboring the reconstructed tou regulatory circuit. Regulator-promoter swapping experiments demonstrated that the presence of TouR is necessary and sufficient for imposing gratuitous activation on the Ptou promoter, as well as on other sigma(54)-dependent catabolic promoters, whereas the highly similar phenol-responsive activator DmpR is unable to activate the Ptou promoter in the absence of effectors. We show that this phenomenon is specifically triggered by carbon source exhaustion but not by nitrogen starvation. An updated model of the tou regulatory circuit is presented.

Bacterial transcriptional regulators for degradation pathways of aromatic compounds

Human activities have resulted in the release and introduction into the environment of a plethora of aromatic chemicals. The interest in discovering how bacteria are dealing with hazardous environmental pollutants has driven a large research community and has resulted in important biochemical, genetic, and physiological knowledge about the degradation capacities of microorganisms and their application in bioremediation, green chemistry, or production of pharmacy synthons. In addition, regulation of catabolic pathway expression has attracted the interest of numerous different groups, and several catabolic pathway regulators have been exemplary for understanding transcription control mechanisms. More recently, information about regulatory systems has been used to construct whole-cell living bioreporters that are used to measure the quality of the aqueous, soil, and air environment. The topic of biodegradation is relatively coherent, and this review presents a coherent overview of the regulatory systems involved in the transcriptional control of catabolic pathways. This review summarizes the different regulatory systems involved in biodegradation pathways of aromatic compounds linking them to other known protein families. Specific attention has been paid to describing the genetic organization of the regulatory genes, promoters, and target operon(s) and to discussing present knowledge about signaling molecules, DNA binding properties, and operator characteristics, and evidence from regulatory mutants. For each regulator family, this information is combined with recently obtained protein structural information to arrive at a possible mechanism of transcription activation. This demonstrates the diversity of control mechanisms existing in catabolic pathways.

The sigma54 regulon (sigmulon) of Pseudomonas putida

sigma54 is unique among the bacterial sigma factors. Besides not being related in sequence with the rest of such factors, its mechanism of transcription initiation is completely different and requires the participation of a transcription activator. In addition, whereas the rest of the alternative sigma factors use to be involved in transcription of somehow related biological functions, this is not the case for sigma54 and many different and unrelated genes have been shown to be transcribed from sigma54-dependent promoters, ranging from flagellation, to utilization of several different carbon and nitrogen sources, or alginate biosynthesis. These genes have been characterized in many different bacterial species and, only until recently with the arrival of complete genome sequences, we have been able to look at the sigma54 functional role from a genomic perspective. Aided by computational methods, the sigma54 regulon has been studied both in Escherichia coli, Salmonella typhimurium and several species of the Rhizobiaceae. Here we present the analysis of the sigma54 regulon (sigmulon) in the complete genome of Pseudomonas putida KT2440. We have developed an improved method for the prediction of sigma54-dependent promoters which combines the scores of sigma54-RNAP target sequences and those of activator binding sites. In combination with other evidence obtained from the chromosomal context and the similarity with closely related bacteria, we have been able to predict more than 80% of the sigma54-dependent promoters of P. putida with high confidence. Our analysis has revealed new functions for sigma54 and, by means of comparative analysis with the previous studies, we have drawn a potential mechanism for the evolution of this regulatory system.

Transient XylR binding to the UAS of the Pseudomonas putida sigma54 promoter Pu revealed with high intensity UV footprinting in vivo

The binding of the transcriptional regulator XylR to its cognate upstream activating sequences (UAS) of the sigma54-dependent promoter Pu of Pseudomonas putida has been examined in vivo in single copy gene dose and stoichiometry. To this end, we have employed a novel in vivo genomic footprinting procedure that uses short exposures of bacterial cells to diffuse high intensity UV light that causes formation of TT or TC dimers. In contrast to simpler models for activation of sigma54-dependent promoters, our results clearly indicate that the XylR protein is not permanently bound in vivo to its target sites in Pu. On the contrary, the UAS appear to be mostly unoccupied at all growth stages. This is in contrast to the integration host factor (IHF), which binds Pu strongly in vivo at stationary phase, as also revealed by UV footprinting. Only overexpression of XylR altered the photoreactivity of the corresponding DNA region to report stable binding of the regulator to the UAS. However, the presence of aromatic XylR inducers reversed the forced occupation caused by increased levels of the activator. These results are compatible with the notion that XylR interacts very transiently with the UAS and detaches from the promoter during transcriptional activation of Pu.

Recruitment of sigma54-RNA polymerase to the Pu promoter of Pseudomonas putida through integration host factor-mediated positioning switch of alpha subunit carboxyl-terminal domain on an UP-like element

The interactions between the sigma54-containing RNA polymerase (sigma54-RNAP) and the region of the Pseudomonas putida Pu promoter spanning from the enhancer to the binding site for the integration host factor (IHF) were analyzed both by DNase I and hydroxyl radical footprinting. A short Pu region centered at position -104 was found to be involved in the interaction with sigma54-RNAP, both in the absence and in the presence of IHF protein. Deletion or scrambling of the -104 region strongly reduced promoter affinity in vitro and promoter activity in vivo, respectively. The reduction in promoter affinity coincided with the loss of IHF-mediated recruitment of the sigma54-RNAP in vitro. The experiments with oriented-alpha sigma54-RNAP derivatives containing bound chemical nuclease revealed interchangeable positioning of only one of the two alpha subunit carboxyl-terminal domains (alphaCTDs) both at the -104 region and in the surroundings of position -78. The addition of IHF resulted in perfect position symmetry of the two alphaCTDs. These results indicate that, in the absence of IHF, the sigma54-RNAP asymmetrically uses only one alphaCTD subunit to establish productive contacts with upstream sequences of the Pu promoter. In the presence of IHF-induced curvature, the closer proximity of the upstream DNA to the body of the sigma54-RNAP can allow the other alphaCTD to be engaged in and thus favor closed complex formation.

Quantitative structure-activity relationship (QSAR) analysis of aromatic effector specificity in NtrC-like transcriptional activators from aromatic oxidizing bacteria

A quantitative structure-activity relationship (QSAR) approach was taken to provide mechanistic insights into the interaction between the chemical structure of inducing compounds and the transcriptional activation of aromatic monooxygenase operons among the XylR/DmpR subclass of bacterial NtrC-like transcriptional regulators. Compared to XylR and DmpR, a broader spectrum of effector compounds was observed for the TbuT system from Ralstonia pickettii PKO1. The results of QSAR analysis for TbuT suggested that a steric effect, rather than hydrophobic or electronic effects, may be the predominant factor in determining aromatic effector specificity, and the active site of the regulator may positively interact not only with the methyl moiety but also with the most electron-rich aryl side of an aromatic effector.

Identification and physical characterization of the HbpR binding sites of the hbpC and hbpD promoters

Pseudomonas azelaica HBP1 can use 2-hydroxybiphenyl (2-HBP) and 2,2'-dihydroxybiphenyl as sole carbon and energy sources by means of the hbp regulon. This regulon is composed of three genes, hbpCA and hbpD, coding for enzymes of a meta-cleavage pathway and the hbpR gene, which codes for a XylR/DmpR-type transcription regulator. It was previously shown that HbpR activates transcription from two sigma(54)-dependent promoters, P(hbpC) and P(hbpD), in the presence of 2-HBP. In this study, by using gel mobility shift assays with a purified fusion protein containing calmodulin binding protein (CBP) and HbpR, we detected two binding regions for HbpR in P(hbpC) and one binding region in P(hbpD). DNase I footprints of the proximal binding region of P(hbpC) and of the binding region in P(hbpD) showed that CBP-HbpR protected a region composed of two inverted repeat sequences which were homologous to the binding sites identified for XylR. Unlike the situation in the XylR/P(u) system, we observed simultaneous binding of CBP-HbpR on the two upstream activating sequences (UASs). Fragments with only one UAS did not show an interaction with HbpR, indicating that both pairs of UASs are needed for HbpR binding. The addition of both ATP and 2-HBP increased the DNA binding affinity of HbpR. These results showed for the first time that, for regulators of the XylR/DmpR type, the effector positively affects the recruitment of the regulatory protein on the enhancer DNA.

Integration of global regulation of two aromatic-responsive sigma(54)-dependent systems: a common phenotype by different mechanisms

Pseudomonas-derived regulators DmpR and XylR are structurally and mechanistically related sigma(54)-dependent activators that control transcription of genes involved in catabolism of aromatic compounds. The binding of distinct sets of aromatic effectors to these regulatory proteins results in release of a repressive interdomain interaction and consequently allows the activators to promote transcription from their cognate target promoters. The DmpR-controlled Po promoter region and the XylR-controlled Pu promoter region are also similar, although homology is limited to three discrete DNA signatures for binding sigma(54) RNA polymerase, the integration host factor, and the regulator. These common properties allow cross-regulation of Pu and Po by DmpR and XylR in response to appropriate aromatic effectors. In vivo, transcription of both the DmpR/Po and XylR/Pu regulatory circuits is subject to dominant global regulation, which results in repression of transcription during growth in rich media. Here, we comparatively assess the contribution of (p)ppGpp, the FtsH protease, and a component of an alternative phosphoenolpyruvate-sugar phosphotransferase system, which have been independently implicated in mediating this level of regulation. Further, by exploiting the cross-regulatory abilities of these two circuits, we identify the target component(s) that are intercepted in each case. The results show that (i) contrary to previous speculation, FtsH is not universally required for transcription of sigma(54)-dependent systems; (ii) the two factors found to impact the XylR/Pu regulatory circuit do not intercept the DmpR/Po circuit; and (iii) (p)ppGpp impacts the DmpR/Po system to a greater extent than the XylR/Pu system in both the native Pseudomonas putida and a heterologous Escherichia coli host. The data demonstrate that, despite the similarities of the specific regulatory circuits, the host global regulatory network latches onto and dominates over these specific circuits by exploiting their different properties. The mechanistic implications of how each of the host factors exerts its action are discussed.

Monitoring intracellular levels of XylR in Pseudomonas putida with a single-chain antibody specific for aromatic-responsive enhancer-binding proteins

We have isolated a recombinant phage antibody (Phab) that binds a distinct epitope of the subclass of the sigma(54)-dependent prokaryotic enhancer-binding proteins that respond directly to aromatic effectors, e.g., those that activate biodegradative operons of Pseudomonas spp. The DNA segments encoding the variable (V) domains of the immunoglobulins expressed by mice immunized with the C-terminal half of TouR (TouRDeltaA) of Pseudomonas stutzeri OX1 were amplified and rearranged in vitro as single-chain Fv (scFv) genes. An scFv library was thereby constructed, expressed in an M13 display system, and subjected to a panning procedure with TouR. One clone (named B7) was selected with high affinity for TouR and XylR (the regulator of the upper TOL operon of the pWW0 plasmid). The epitope recognized by this Phab was mapped to the peptide TPRAQATLLRVL, which seems to be characteristic of the group of enhancer-binding proteins to which TouR and XylR belong and which is located adjacent to the Walker B motif of the proteins. The Phab B7 was instrumental in measuring directly the intracellular levels of XylR expressed from its natural promoter in monocopy gene dosage in Pseudomonas putida under various conditions. Growth stage, the physical form of the protein produced (XylR or XylRDeltaA), and the presence or absence of aromatic inducers in the medium influenced the intracellular pool of these molecules. XylR oscillated from a minimum of approximately 30 molecules (monomers) per cell during exponential phase to approximately140 molecules per cell at stationary phase. Activation of XylR by aromatic inducers decreased the intracellular concentration of the regulator. The levels of the constitutively active variant of XylR named XylRDeltaA were higher, fluctuating between approximately 90 and approximately 570 molecules per cell, depending on the growth stage. These results are compatible with the present model of transcriptional autoregulation of XylR and suggest the existence of mechanisms controlling the stability of XylR protein in vivo.

Analysis of transcription of the bph locus of Burkholderia sp. strain LB400 and evidence that the ORF0 gene product acts as a regulator of the bphA1 promoter

Although gene clusters for the degradation of biphenyls and polychlorobiphenyls have been extensively characterized, comparatively little is known about the regulation of their expression. In the present work, different aspects of transcription of the bph locus of the potent polychlorobiphenyl degrader Burkholderia sp. strain LB400 were investigated. An RNA blot analysis of the entire gene cluster revealed that the transcription of all genes encoding biphenyl catabolic enzymes responded similarly to the presence of biphenyl, succinate or a mixture of the two. One region of the locus, encompassing ORF0, was separately transcribed and differently regulated. A single start position was mapped for this monocistronic transcript. Synthesis of the adjacent RNA, encoding subunits of biphenyl dioxygenase, was strongly biphenyl-inducible. In this case, four major 5'-ends were mapped between 25 and 70 bp upstream of the start codon of gene bphA1. Sequence elements between approximately positions 710 and 1080 upstream were required in cis for full functioning of the respective promoter(s) (P(bphA1)). ORF0(-) mutants of strain LB400 retained the ability to grow on biphenyl, but showed decreased concentrations of bphA1A2 RNA and decreased lacZ expression in strains harbouring a reporter system with a bphA1-lacZ transcriptional fusion. This effect was compensated by the introduction of an intact ORF0 in trans, indicating that the ORF0 gene product mediates activation of P(bphA1).

Unusual location of two nearby pairs of upstream activating sequences for HbpR, the main regulatory protein for the 2-hydroxybiphenyl degradation pathway of "Pseudomonas azelaica" HBP1

"Pseudomonas azelaica" HBP1 degrades 2-hydroxybiphenyl (2-HBP) and 2,2'-diHBP by employing a meta-cleavage pathway encoded by the hbpCAD genes. The regulatory gene hbpR, located directly upstream of the hbpCAD genes and oriented in the opposite direction, encodes a transcription activator protein belonging to the so-called XylR/DmpR subclass within the NtrC family. HbpR activates transcription from two separate sigma(54)-dependent promoters upstream of the hbpC and the hbpD genes, in the presence of the pathway substrates 2-HBP and 2,2'-diHBP. The DNA region upstream of the hbpC gene displays an unusual organization, containing two adjacent 0.3 kb regions that share 71% sequence identity. The DNA region most proximal to the hbpC promoter harbours one pair of putative upstream activating sequences (UASs C-1/C-2) and a small cryptic ORF that shows homology to hbpR itself. The second, more distal, region contains a second pair of putative UASs (UASs C-3/4) and the 5'-part of the hbpR gene. Transcriptional fusions in Escherichia coli between different deletions of the hbpR-hbpC intergenic region and the genes for bacterial luciferase revealed that most if not all of the transcriptional output from the hbpC promoter is mediated from the proximal UASs C-1/C-2. However, when the UASs C-1/C-2 were deleted and UASs C-3/C-4 were placed in an appropriate position with respect to the promoter region, the hbpC promoter was still inducible with 2-HBP, albeit at a lower level. Transcription studies in E. coli and "P. azelaica" revealed that the divergently oriented hbpR gene is expressed constitutively from a sigma(70)-dependent promoter situated within the cryptic ORF. The presence of UAS pair C-3/C-4 mediated a slightly higher promoter activity for transcription of hbpR.

In vivo and in vitro effects of integration host factor at the DmpR-regulated sigma(54)-dependent Po promoter

Transcription from the Pseudomonas CF600-derived sigma(54)-dependent promoter Po is controlled by the aromatic-responsive activator DmpR. Here we examine the mechanism(s) by which integration host factor (IHF) stimulates DmpR-activated transcriptional output of the Po promoter both in vivo and in vitro. In vivo, the Po promoter exhibits characteristics that typify many sigma(54)-dependent promoters, namely, a phasing-dependent tolerance with respect to the distance from the regulator binding sites to the distally located RNA polymerase binding site, and a strong dependence on IHF for optimal promoter output. IHF is shown to affect transcription via structural repercussions mediated through binding to a single DNA signature located between the regulator and RNA polymerase binding sites. In vitro, using DNA templates that lack the regulator binding sites and thus bypass a role of IHF in facilitating physical interaction between the regulator and the transcriptional apparatus, IHF still mediates a DNA binding-dependent stimulation of Po transcription. This stimulatory effect is shown to be independent of previously described mechanisms for the effects of IHF at sigma(54) promoters such as aiding binding of the regulator or recruitment of sigma(54)-RNA polymerase via UP element-like DNA. The effect of IHF could be traced to promotion and/or stabilization of open complexes within the nucleoprotein complex that may involve an A+T-rich region of the IHF binding site and promoter-upstream DNA. Mechanistic implications are discussed in the context of a model in which IHF binding results in transduction of DNA instability from an A+T-rich region to the melt region of the promoter.

Transcriptional organization and dynamic expression of the hbpCAD genes, which encode the first three enzymes for 2-hydroxybiphenyl degradation in Pseudomonas azelaica HBP1

Pseudomonas azelaica HBP1 degrades the toxic substance 2-hydroxybiphenyl (2-HBP) by means of three enzymes that are encoded by structural genes hbpC, hbpA, and hbpD. These three genes form a small noncontiguous cluster. Their expression is activated by the product of regulatory gene hbpR, which is located directly upstream of the hbpCAD genes. The HbpR protein is a transcription activator and belongs to the so-called XylR/DmpR subclass within the NtrC family of transcriptional activators. Transcriptional fusions between the different hbp intergenic regions and the luxAB genes of Vibrio harveyi in P. azelaica and in Escherichia coli revealed the existence of two HbpR-regulated promoters; one is located in front of hbpC, and the other one is located in front of hbpD. Northern analysis confirmed that the hbpC and hbpA genes are cotranscribed, whereas the hbpD gene is transcribed separately. No transcripts comprising the entire hbpCAD cluster were detected, indicating that transcription from P(hbpC) is terminated after the hbpA gene. E. coli mutant strains lacking the structural genes for the RNA polymerase sigma(54) subunit or for the integration host factor failed to express bioluminescence from P(hbpC)- and P(hbpD)-luxAB fusions when a functional hbpR gene was provided in trans. This pointed to the active role of sigma(54) and integration host factor in transcriptional activation from these promoters. Primer extension analysis revealed that both P(hbpC) and P(hbpD) contain the typical motifs at position -24 (GG) and -12 (GC) found in sigma(54)-dependent promoters. Analysis of changes in the synthesis of the hbp mRNAs, in activities of the 2-HBP pathway enzymes, and in concentrations of 2-HBP intermediates during the first 4 h after induction of continuously grown P. azelaica cells with 2-HBP demonstrated that the specific transcriptional organization of the hbp genes ensured smooth pathway expression.

Visualization of DNA-protein intermediates during activation of the Pu promoter of the TOL plasmid of Pseudomonas putida

The ATP-dependent multimerization process undergone by the sigma(54)-dependent activator XylR of the TOL plasmid pWW0 of Pseudomonas putida when bound to the upstream activating sequences (UAS) of the cognate PU: promoter was examined by transmission electron microscopy (TEM). To this end, supercoiled DNA templates were combined with increasing concentrations of the constitutive XylR variant XylRDeltaA, with or without ATP or its non-hydrolysable analogue ATPgammaS, and the resulting complexes were visualized by TEM. The different types of DNA-protein association were analysed and a statistical study of the frequency of the various forms was made. ATP appeared to establish an equilibrium between different molecular associations, as well as major changes in the physical shape of the DNA-protein complexes. The formation of higher nucleoprotein structures frequently bearing DNA bends became manifest. Such complexes often engaged otherwise separated UAS-containing plasmids, indicating that the ATP-driven multimer included XylR molecules recruited in trans. Whilst ATP caused the different types of XylR-DNA complex to occur at quite balanced frequencies, ATPgammaS appeared to displace the distribution predominantly towards the higher order forms. These data are compatible with the notion that each time ATP is hydrolysed the transcriptional activation complex is disassembled.

In vivo and in vitro effects of (p)ppGpp on the sigma(54) promoter Pu of the TOL plasmid of Pseudomonas putida

The connection between the physiological control of the sigma(54)-dependent Pu promoter of the TOL plasmid pWW0 of Pseudomonas putida and the stringent response mediated by the alarmone (p)ppGpp has been examined in vivo an in vitro. To this end, the key regulatory elements of the system were faithfully reproduced in an Escherichia coli strain and assayed as lacZ fusions in various genetic backgrounds lacking (p)ppGpp or overexpressing relA. Neither the responsiveness of Pu to 3-methyl benzylalcohol mediated by its cognate activator XylR nor the down-regulation of the promoter by rapid growth were affected in relA/spoT strains to an extent which could account for the known physiological control that governs this promoter. Overexpression of the relA gene [predicted to increase intracellullar (p)ppGpp levels] did, however, cause a significant gain in Pu activity. Since such a gain might be the result of indirect effects, we resorted to an in vitro transcription system to assay directly the effect of ppGpp on the transcriptional machinery. Although we did observe a significant increase in Pu performance through a range of sigma(54)-RNAP concentrations, such an increase never exceeded twofold. The difference between these results and the behavior of the related Po promoter of the phenol degradation plasmid pVI150 could be traced to the different promoter sequences, which may dictate the type of metabolic signals recruited for the physiological control of sigma(54)-systems.

Analysis of the domain structure and the DNA binding site of the transcriptional activator FhlA

FhlA is the transcriptional activator of the genes coding for the formate hydrogen lyase system in Escherichia coli. It is activated by the binding of formate and induces transcription by sigma54 RNA polymerase after binding to specific upstream activating sequences (UAS). Sequence comparison had shown that FhlA exhibits a structure composed of three domains, which is typical for sigma54-dependent regulators. By analyzing the N-terminal domain of FhlA of E. coli (amino acids 1-378; FhlA-N) and the rest of the protein (amino acids 379-693; FhlA-C) as separate proteins in vivo and in vitro the functions of the different domains of FhlA were elucidated. The FhlA-C domain is active in ATP hydrolysis and activation of transcription and its activity is neither influenced by the presence of formate nor of the antiactivator HycA. However, it is stimulated in the presence of the FhlA-specific UAS, indicating that this region of FhlA is responsible for DNA binding. FhlA-N is not active itself but able to reduce the activity of full-length FhlA in trans, probably by formation of nonfunctional heterooligomers. The DNA binding site of FhlA was analyzed by hydroxyradical footprinting. Each UAS consists of two binding sites of 16 bp separated by a spacer region. A consensus sequence could be deduced and a model is presented and supported by in vivo data in which a FhlA tetramer binds to the UAS on one side of the DNA helix. Performing an extensive screening we could show that the FhlA regulatory system is conserved in different species of the family Enterobacteriaceae. The analysis of orthologs of FhlA revealed that they are able to functionally replace the E. coli enzyme.

Compilation and analysis of sigma(54)-dependent promoter sequences

Promoters recognized by the RNA-polymerase with the alternative sigma factor sigma(54) (Esigma54) are unique in having conserved positions around -24 and -12 nucleotides upstream from the transcriptional start site, instead of the typical -35 and -10 boxes. Here we compile 186 -24/-12 promoter sequences reported in the literature and generate an updated and extended consensus sequence. The use of the extended consensus increases the probability of identifying genuine -24/-12 promoters. The effect of several reported mutations at the -24/-12 elements on RNA-polymerase binding and promoter strength is discussed in the light of the updated consensus.

In vivo and in vitro activities of the Escherichia coli sigma54 transcription activator, PspF, and its DNA-binding mutant, PspFDeltaHTH

Transcription of the phage-shock protein (psp) operon in Escherichia coli is driven by a sigma54 promoter, stimulated by integration host factor and dependent on an upstream, cis-acting sequence and an activator protein, PspF. PspF belongs to the enhancer binding protein family but lacks an N-terminal regulatory domain. Purified PspF is not modified and has an ATPase activity that is increased twofold in the presence of DNA carrying the psp cis-acting sequence. Purified mutant His-tagged PspF that lacks the C-terminal DNA-binding motif has a DNA-independent ATPase activity when present at 30-fold the concentration of the wild-type protein. Both proteins oligomerize in solution in an ATP and DNA-independent manner. The wild-type activator protein, but not the DNA-binding mutant, binds specifically to the cis-acting sequence. Analysis of the sequence protected by PspF demonstrates the presence of two upstream binding sites within the sequence, UAS I and UAS II, which together constitute the psp enhancer. Protection at low protein concentrations is more pronounced and more extensive on a supercoiled DNA than on a linear template. Full expression of the psp operon upon hyperosmotic shock depends on wild-type PspF, but only partially requires the presence of the psp enhancer.

Binding of the fur (ferric uptake regulator) repressor of Escherichia coli to arrays of the GATAAT sequence

The mode of DNA binding of the Fur (ferric uptake regulator) repressor which controls transcription of iron-responsive genes in Escherichia coli, has been re-examined. Using as a reference the known sites at the promoter of the aerobactin operon of Escherichia coli, we have compared in detail the patterns of interaction between the purified Fur protein and natural or synthetic DNA targets. DNase I and hydroxyl radical footprinting, as well as missing-T assays, consistently revealed that functional Fur sites are composed of a minimum of three repeats of the hexameric motif GATAAT rather than by a palindromic 19 bp target sequence. Extended binding sites, constructed by stepwise addition of one or two direct repeats of the same sequence, were occupied co-operatively by Fur with the same pattern of interactions as those observed with the core of three repeats. This indicated that functional sites with a range of affinities can be formed by the addition of discrete GATAAT extensions to a minimal recognition sequence. The fashion in which Fur binds its target, virtually unknown in prokaryotic transcriptional regulators, accounts for the observed helical wrapping of the protein around the DNA helix.

Active recruitment of sigma54-RNA polymerase to the Pu promoter of Pseudomonas putida: role of IHF and alphaCTD

The sequence elements determining the binding of the sigma54-containing RNA polymerase (sigma54-RNAP) to the Pu promoter of Pseudomonas putida have been examined. Contrary to previous results in related systems, we show that the integration host factor (IHF) binding stimulates the recruitment of the enzyme to the -12/-24 sequence motifs. Such a recruitment, which is fully independent of the activator of the system, XylR, requires the interaction of the C-terminal domain of the alpha subunit of RNAP with specific DNA sequences upstream of the IHF site which are reminiscent of the UP elements in sigma70 promoters. Our data show that this interaction is mainly brought about by the distinct geometry of the promoter region caused by IHF binding and the ensuing DNA bending. These results support the view that binding of sigma54-RNAP to a promoter is a step that can be subjected to regulation by factors (e.g. IHF) other than the sole intrinsic affinity of sigma54-RNAP for the -12/-24 site.

Modulation of the function of the signal receptor domain of XylR, a member of a family of prokaryotic enhancer-like positive regulators

The XylR protein controls expression from the Pseudomonas putida TOL plasmid upper pathway operon promoter (Pu) in response to aromatic effectors. XylR-dependent stimulation of transcription from a Pu::lacZ fusion shows different induction kinetics with different effectors. With toluene, activation followed a hyperbolic curve with an apparent K of 0.95 mM and a maximum beta-galactosidase activity of 2,550 Miller units. With o-nitrotoluene, in contrast, activation followed a sigmoidal curve with an apparent K of 0.55 mM and a Hill coefficient of 2.65. m-Nitrotoluene kept the XylR regulator in an inactive transcriptional form. Therefore, upon binding of an effector, the substituent on the aromatic ring leads to productive or unproductive XylR forms. The different transcriptional states of the XylR regulator are substantiated by XylR mutants. XylRE172K is a mutant regulator that is able to stimulate transcription from the Pu promoter in the presence of m-nitrotoluene; however, its response to m-aminotoluene was negligible, in contrast with the wild-type regulator. These results illustrate the importance of the electrostatic interactions in effector recognition and in the stabilization of productive and unproductive forms by the regulator upon aromatic binding. XylRD135N and XylRD135Q are mutant regulators that are able to stimulate transcription from Pu in the absence of effectors, whereas substitution of Glu for Asp135 in XylRD135E resulted in a mutant whose ability to recognize effectors was severely impaired. Therefore, the conformation of mutant XylRD135Q as well as XylRD135N seemed to mimic that of the wild-type regulator when effector binding occurred, whereas mutant XylRD135E seemed to be blocked in a conformation similar to that of wild-type XylR and XylRE172K upon binding to an inhibitor molecule such as m-nitrotoluene or m-aminotoluene.

Activation of the toluene-responsive regulator XylR causes a transcriptional switch between sigma54 and sigma70 promoters at the divergent Pr/Ps region of the TOL plasmid

The mechanism by which XylR, the toluene-responsive activator of the sigma54-dependent Pu and Ps promoters of the Pseudomonas TOL plasmid pWW0, downregulates its own sigma70 promoter Prhas been examined. An in vitro transcription system was developed in order to reproduce the repression of Probserved in cells of P. putida (pWW0) both in the presence and in the absence of the XylR inducer, benzyl alcohol. DNA templates bearing the two sigma70-RNA polymerase (RNAP) binding sites of Pr, which overlap the upstream activating sequences (UAS) for XylR in the divergent sigma54 promoter Ps, were transcribed in the presence of a constitutively active XylR variant deleted of its N-terminal domain (XylRdeltaA). The addition of ATP, known to trigger multimerization of the regulator at the UAS, enhanced the repression of Pr by XylR. Furthermore, we observed activation of the divergent sigma54 promoter Ps during Pr downregulation by XylRdeltaA. These results support the notion that activation of XylR by aromatic inducers in vivo triggers a transcriptional switch between Pr and Ps. Such a switch is apparently caused by the ATP-dependent multimerization and strong DNA binding of the protein required for activation of the sigma54 promoter. This device could reset the level of XylR expression during activation of the sigma54 Pu and Ps promoters of the TOL plasmid.

Transcriptional control of the Pseudomonas TOL plasmid catabolic operons is achieved through an interplay of host factors and plasmid-encoded regulators

The xyl genes of Pseudomonas putida TOL plasmid that specify catabolism of toluene and xylenes are organized in four transcriptional units: the upper-operon xylUWCAMBN for conversion of toluene/xylenes into benzoate/alkylbenzoates; the meta-operon xylXYZLTEGFJQKIH, which encodes the enzymes for further conversion of these compounds into Krebs cycle intermediates; and xylS and xylR, which are involved in transcriptional control. The XylS and XylR proteins are members of the XylS/AraC and NtrC families, respectively, of transcriptional regulators. The xylS gene is constitutively expressed at a low level from the Ps2 promoter. The XylS protein is activated by interaction with alkylbenzoates, and this active form stimulates transcription from Pm by sigma70- or sigmaS-containing RNA polymerase (the meta loop). The xylR gene is also expressed constitutively. The XylR protein, which in the absence of effectors binds in a nonactive form to target DNA sequences, is activated by aromatic hydrocarbons and ATP; it subsequently undergoes multimerization and structural changes that result in stimulation of transcription from Pu of the upper operon. This latter process is assisted by the IHF protein and mediated by sigma54-containing RNA polymerase. Once activated, the XylR protein also stimulates transcription from the Ps1 promoter of xylS without interfering with expression from Ps2. This process is assisted by the HU protein and is mediated by sigma54-containing RNA polymerase. As a consequence of hyperexpression of the xylS gene, the XylS protein is hyperproduced and stimulates transcription from Pm even in the absence of effectors (the cascade loop). The two sigma54-dependent promoters are additionally subject to global (catabolite repression) control.

Expression, inducer spectrum, domain structure, and function of MopR, the regulator of phenol degradation in Acinetobacter calcoaceticus NCIB8250

Degradation of phenol by Acinetobacter calcoaceticus NCIB8250 involves (sigma54-dependent expression of a multicomponent phenol hydroxylase and catechol 1,2-dioxygenase encoded by the mop operon. Complementation of a new mutant deficient in phenol utilization yielded the regulatory locus mopR. It is located in divergent orientation next to the mop operon. MopR is constitutively expressed at a low level from a sigma70-type promoter and belongs to the NtrC family of regulators. The amino acid sequence is similar to that of XylR regulating xylene degradation and to that of DmpR regulating dimethylphenol degradation in Pseudomonas spp. However, it shows a different effector profile for substituted phenols than DmpR. MopR activates phenol hydroxylase expression in the presence of phenol in Escherichia coli, indicating that it binds the effector. The phenol binding A domains of MopR and DmpR have fewer identical residues than the A domains of DmpR and XylR, despite the fact that XylR recognizes different effectors. This suggests that sequence conservation in the A domain does not reflect the potential to bind the respective effectors. Overexpression of the MopR A domain in the presence of wild-type MopR causes loss of mop inducibility by phenol, establishing its negative transdominance over MopR. Deletion of 110 residues from the N terminus did not affect transdominance of the truncated domain, whereas deletion of 150 residues abolished it completely. This result establishes the distinction of two subdomains, A(N) and A(C), which together constitute the A domain. The C-terminal portion of the A domain, A(C), shows considerable affinity for the C domain, even in the presence of the trigger phenol.

ATP binding to the sigma 54-dependent activator XylR triggers a protein multimerization cycle catalyzed by UAS DNA

The events that take place at the prokaryotic enhancer of the Pu promoter of Pseudomonas putida prior to the engagement of the sigma 54-RNA polymerase (sigma 54-RNAP) have been studied in vitro. ATP hydrolysis by XylR, the cognate regulator of the system, is preceded by the multimerization of XylR at the enhancer, which is itself triggered by the sole allosteric effect of ATP binding to the protein. Since ADP is unable to support multimerization, ATP hydrolysis might be followed by a return to the nonmultimerized state. This notion is supported further by the properties of mutant proteins that seem to be frozen, in either the nonmultimerized or the multimerized state, respectively. These results support a cyclic mechanism of ATP-dependent association/dissociation of XylR at the promoter UAS that precedes any involvement of the polymerase in transcription initiation.