A family of positive regulators related to the Pseudomonas putida TOL plasmid XylS and the Escherichia coli AraC activators

Transcriptional control of the Pseudomonas putida TOL plasmid catabolic pathways

TOL plasmid pWW0 of Pseudomonas putida contains two operons that specify a pathway for the degradation of aromatic hydrocarbons. The upper pathway operon encodes the enzymes for the oxidation of toluene/xylenes to benzoate/toluates, and the metacleavage pathway operon encodes the enzymes for the further oxidation of these compounds to Krebs cycle intermediates. Their expression is controlled by the gene products of two divergently transcribed regulatory genes, xyIR and xyIS. The XyIR protein, which belongs to the NtrC family of regulators, is expressed from two tandem promoters and autoregulates its synthesis. XyIR stimulates transcription from the xyIS gene promoter (Ps) and the upper pathway operon promoter (Pu) in the presence of pathway substrates. Both promoters are sigma 54 dependent, and Pu also requires the presence of integration host factor (IHF) for activation of transcription. Binding sites for XyIR and IHF in the Pu promoter and for XyIR in the Ps promoters have been defined. The XyIS protein, which belongs to the AraC family of regulators, stimulates transcription from the meta-cleavage pathway operon promoter (Pm) in the presence of benzoates. The effector binding pocket and DNA-binding region of XyIS have been defined through the isolation of mutants that exhibit altered effector specificity and modified transcriptional patterns, respectively. Expression of the meta-cleavage pathway operon is also induced by xylene-activated XyIR protein via a cascade regulatory system in which this protein, in combination with sigma 54, stimulates the expression from the xyIS promoter.(ABSTRACT TRUNCATED AT 250 WORDS)

Gene expression in Pseudomonas

Gene regulation studies in pseudomonad bacteria are mainly restricted to Pseudomonas aeruginosa and Pseudomonas putida. Constitutive promoters exhibit DNA sequences similar to the σ (70)-dependent constitutive promoters of Escherichia coli. The TOL meta-cleavage pathway operon promoter and the nah operon promoters are the best characterized σ (70)-dependent promoters, which exhibit-10 regions rich in As and Ts and non-conserved-35 regions. The DNA binding motif recognized by the respective positive regulators lies between-40 and-80. Another set of positively controlled promoters exhibit upstream activator sequences located between-100 and-500. Transcription stimulation from some of these promoters also involves σ (54) and/or IHF protein. In this class of promoters, DNA binding is required to establish open complexes. Promoters for the utilization of histidine (hut) are under negative control by the HutC protein. hut promoters exhibit-10/-35 consensus regions and an overlapping operator sequence between-15 and-50. Repression of hut promoters seems to be achieved through steric hindrance of RNA polymerase. Another set of promoters are controlled by catabolite repression, which seems to be cyclic-AMP independent.

The plasmid-encoded urease gene cluster of the family Enterobacteriaceae is positively regulated by UreR, a member of the AraC family of transcriptional activators

Ureolytic clinical isolates of Providencia stuartii, Salmonella spp., and some Escherichia coli strains contain large urease-encoding plasmids. Expression of urease activity from these isolates is induced at least 20-fold by urea. In order to facilitate studies on the regulatory mechanism controlling this urea-inducible expression, the plasmid-encoded urease genes were inserted into the low-copy-number vector pRK415, to form pSEF70. Deletion mutagenesis of pSEF70 demonstrated that between 1.3 and 1.6 kb of DNA upstream of ureD (the first of seven urease genes clustered in an operon-like fashion) was required for a urease-positive phenotype. An open reading frame coding for a 34.1-kDa polypeptide was found in the DNA sequence of this upstream region. This open reading frame has been designated ureR, for urease regulator. A urea-inducible promoter region was identified upstream of ureD. Transcription from this promoter was activated only when ureR was present in trans. The predicted ureR gene product contains a helix-turn-helix motif and shows significant amino acid similarity to the AraC family of transcriptional activators. We conclude that urea-dependent expression from the plasmid-encoded urease gene cluster requires ureR and that ureR codes for a positive regulatory element controlling transcription of at least one essential urease gene, ureD.

Genetic and functional analysis of the multiple antibiotic resistance (mar) locus in Escherichia coli

A 7.8-kbp fragment of chromosomal DNA from a region controlling multiple antibiotic resistance (Mar) in Escherichia coli has been sequenced. Within the fragment is a potential divergent promoter region including marO, which contains two pairs of direct repeats, suggesting possible operator-regulatory sites. To the left of marO (region I) are one or two transcriptional units with three putative open reading frames (ORFs) encoding 64, 157, and 70 amino acids. To the right (region II) is a transcriptional unit containing three putative ORFs (ORF125/144, ORF129, and ORF72). Of six independent Mar mutants, four had mutations within the ORF encoding the first putative protein (ORF125/144) downstream of marO, including three different single-point mutations and an IS2 insertion. One of the other mutations occurred in marO (20-bp duplication), and the other occurred in a site in marO or ORF144 (a 1-bp change). All six mutations led to increased transcription of the region II transcript. High-copy-number plasmids containing marO and the adjacent ORF125/144 region from a wild-type source but not from a Mar mutant reduced the antibiotic resistance of a Mar mutant to levels comparable to those of wild-type cells. High-copy-number plasmids containing wild-type marO alone caused an increase in resistance to tetracycline, chloramphenicol, and norfloxacin in a wild-type strain. The nature of the Mar mutations and the results of the complementation studies suggest that ORF125/144 encodes a repressor (designated MarR) which acts at marO. The second ORF (ORF129), designated marA, would encode a protein, MarA, whose sequence shows strong similarity to those of a family of positive transcriptional regulators. A Tn5 insertion in marA inactivated the multiresistance phenotype of Mar mutants. The function of ORF72, designated marB, encoding the third putative protein in the operon, and that of other ORFs detected within the 7.8-kb fragment have not yet been determined.

Genetic and functional analysis of the multiple antibiotic resistance (mar) locus in Escherichia coli

A 7.8-kbp fragment of chromosomal DNA from a region controlling multiple antibiotic resistance (Mar) in Escherichia coli has been sequenced. Within the fragment is a potential divergent promoter region including marO, which contains two pairs of direct repeats, suggesting possible operator-regulatory sites. To the left of marO (region I) are one or two transcriptional units with three putative open reading frames (ORFs) encoding 64, 157, and 70 amino acids. To the right (region II) is a transcriptional unit containing three putative ORFs (ORF125/144, ORF129, and ORF72). Of six independent Mar mutants, four had mutations within the ORF encoding the first putative protein (ORF125/144) downstream of marO, including three different single-point mutations and an IS2 insertion. One of the other mutations occurred in marO (20-bp duplication), and the other occurred in a site in marO or ORF144 (a 1-bp change). All six mutations led to increased transcription of the region II transcript. High-copy-number plasmids containing marO and the adjacent ORF125/144 region from a wild-type source but not from a Mar mutant reduced the antibiotic resistance of a Mar mutant to levels comparable to those of wild-type cells. High-copy-number plasmids containing wild-type marO alone caused an increase in resistance to tetracycline, chloramphenicol, and norfloxacin in a wild-type strain. The nature of the Mar mutations and the results of the complementation studies suggest that ORF125/144 encodes a repressor (designated MarR) which acts at marO. The second ORF (ORF129), designated marA, would encode a protein, MarA, whose sequence shows strong similarity to those of a family of positive transcriptional regulators. A Tn5 insertion in marA inactivated the multiresistance phenotype of Mar mutants. The function of ORF72, designated marB, encoding the third putative protein in the operon, and that of other ORFs detected within the 7.8-kb fragment have not yet been determined.

The XylS/AraC family of regulators

At least twenty-seven proteins belong to the XylS/AraC family of prokaryote transcriptional regulators. All members of this family except CelD and TetD are positive transcriptional factors. Three subgroups were distinguished within the family in accordance with the Needleman and Wunsch algorithm. Multiple alignment of these proteins revealed that they shared a high degree of sequence homology at their C-terminal end, where a characteristic conserved motif, whose consensus sequence is I-DIA--GF-S--YF--F---G-TPS--R (where - means any aminoacid), was found. Within the homologous C-terminal region, but outside the above consensus motif, a putative DNA-binding domain organized as a helix-turn-helix motif was located in all regulators. For regulators recognizing chemical signals, the non-homologous N-terminal region of these regulators is presumed to contain binding sites for activator molecules that confer specificity.

Definition of nitrite and nitrate response elements at the anaerobically inducible Escherichia coli nirB promoter: interactions between FNR and NarL

Transcription initiation at the Escherichia coli nirB promoter is induced by anaerobic growth and further increased by the presence of nitrite or nitrate in the growth medium. Expression from this promoter is totally dependent on the transcription factor, FNR, which binds between positions -52 and -30 upstream of the transcription startsite. The 20 base pairs from position -79 to -60 contain an inverted repeat of two 10-base sequence elements that are related to sequences at the NarL-binding site at the E. coli narG promoter. Comparison of these, and sequence elements at other promoters regulated by NarL, suggests a consensus NarL-binding sequence. Mutations in the putative NarL-binding site at the nirB promoter decrease FNR-dependent anaerobic induction, suggesting that NarL acts as a helper to FNR during transcription activation. These mutations also suppress induction by nitrite: single mutations at symmetry-related positions have similar effects, whilst double mutations have more severe effects, probably because two NarL subunits bind to the inverted repeat. Disruption of narL decreases nitrite induction of the nirB promoter whilst not suppressing induction by nitrate, suggesting that there may be a second nitrate-responsive factor. Nitrate induction was, however, suppressed by double mutations at symmetry-related positions in the NarL-binding site, suggesting that this putative second factor may bind to sequences similar to those recognized by NarL.

Molecular mechanisms of genetic adaptation to xenobiotic compounds

Microorganisms in the environment can often adapt to use xenobiotic chemicals as novel growth and energy substrates. Specialized enzyme systems and metabolic pathways for the degradation of man-made compounds such as chlorobiphenyls and chlorobenzenes have been found in microorganisms isolated from geographically separated areas of the world. The genetic characterization of an increasing number of aerobic pathways for degradation of (substituted) aromatic compounds in different bacteria has made it possible to compare the similarities in genetic organization and in sequence which exist between genes and proteins of these specialized catabolic routes and more common pathways. These data suggest that discrete modules containing clusters of genes have been combined in different ways in the various catabolic pathways. Sequence information further suggests divergence of catabolic genes coding for specialized enzymes in the degradation of xenobiotic chemicals. An important question will be to find whether these specialized enzymes evolved from more common isozymes only after the introduction of xenobiotic chemicals into the environment. Evidence is presented that a range of genetic mechanisms, such as gene transfer, mutational drift, and genetic recombination and transposition, can accelerate the evolution of catabolic pathways in bacteria. However, there is virtually no information concerning the rates at which these mechanisms are operating in bacteria living in nature and the response of such rates to the presence of potential (xenobiotic) substrates. Quantitative data on the genetic processes in the natural environment and on the effect of environmental parameters on the rate of evolution are needed.

XylS domain interactions can be deduced from intraallelic dominance in double mutants of Pseudomonas putida

The XylS protein is the positive regulator of the TOL plasmid-encoded meta-cleavage pathway for the metabolism of alkylbenzoates in Pseudomonas putida. This protein is activated by a variety of benzoate analogues. To elucidate the functional domains of the regulator and their interactions, several fusions of the XylS C-terminus to MS2 polymerase and of the N-terminus to beta-galactosidase were constructed but all are inactive. In addition, 15 double mutant xylS genes were constructed in vitro by fusing parts of various mutant genes to produce mutant regulators exhibiting C-terminal and N-terminal amino acid substitutions. The phenotypic properties of the parental single mutant genes, and those of the double mutant genes, suggest that the C-terminal region is involved in binding to DNA sequences at the promoter of the meta-cleavage pathway operon, and that the benzoate effector binding pocket includes critical residues present at both the N-terminal and C-terminal ends of the protein. The intraallelic dominance of the Ile229 (Ser229-->Ile) and Val274 (Asp274-->Val) substitutions over the N-terminal His41 (Arg41-->His) substitution, and the intraallelic dominance of Thr45 (Arg45-->Thr) over Ile229 and Val274, support the proposal that these two regions of the regulator interact functionally. Combination of the Leu88 (Trp88-->Leu) and Arg256 (Pro256-->Arg) substitutions did not suppress the semiconstitutive phenotype conferred by Leu88, but resulted in a protein with altered ability to recognize benzoates. In contrast, the Leu88 semiconstitutive phenotype was suppressed by Val288 (Asp288-->Val), and the double mutant was susceptible to activation by benzoates.(ABSTRACT TRUNCATED AT 250 WORDS)

The virulence gene activator ToxT from Vibrio cholerae is a member of the AraC family of transcriptional activators

Virulence gene expression in Vibrio cholerae is postulated to involve ToxR-dependent activation of the toxT gene followed by ToxT activation of virulence genes, including several of those involved in biogenesis of the toxin-coregulated pilus. ToxR is a transmembrane, DNA-binding protein which is a member of the OmpR subclass of two-component activator systems in bacteria. Data presented in this report demonstrate that ToxT is similar to the AraC family of transcriptional activators identified in a variety of gram-negative bacteria. The toxT open reading frame begins approximately 200 nucleotides from the end of the tcpF gene, which is part of a cluster of genes responsible for production of the toxin-coregulated pilus. Accumulation of toxT specific mRNA is ToxR dependent and is modulated by environmental conditions that modulate expression of the regulon. Within the intergenic region between tcpF and toxT is a potential stem-loop structure of an unusual nature which may play a role in regulating expression of toxT mRNA. Experiments with tcpF and toxT cloned behind a strong, constitutive promoter suggest that the two genes can be cotranscribed, but Northern (RNA) blot analysis of V. cholerae suggests that if they are, steady-state levels of their messages may be controlled by a posttranscriptional mechanism. Possible mechanisms for ToxR-dependent expression of toxT are discussed.

Overexpression, purification and characterization of the Escherichia coli MelR transcription activator protein

The gene encoding Escherichia coli MelR protein has been cloned in the expression vector pJLA502. MelR has been overexpressed, substantially purified and shown to bind to DNA fragments carrying the melAB promoter. A truncated version of the melR gene, encoding the C-terminal half of MelR, was also cloned into pJLA502; the protein product of this truncated gene binds to the melAB promoter but was not overproduced. A number of amino acid substitutions were made in the recognition helices of two putative helix-turn-helix motifs in the C-terminal part of MelR, and the effects of these mutations on MelR-dependent transcription initiation at the melAB promoter have been measured.

Evidence that the hrpB gene encodes a positive regulator of pathogenicity genes from Pseudomonas solanacearum

The hrp gene cluster of Pseudomonas solanacearum GMI1000 strain encodes functions that are essential for pathogenicity on tomato and for the elicitation of the hypersensitive response on tobacco. In this study, we present the nucleotide sequence of one of the hrp genes (hrpB) located at the left-hand end of the cluster and we show that hrpB encodes a positive regulator controlling the expression of hrp genes. hrpB has a coding capacity for a 477-amino-acid polypeptide, which shows significant similarity to several prokaryotic transcriptional activators including the AraC protein of Escherichia coli, the XylS protein of Pseudomonas putida and the VirF protein of Yersinia enterocolitica. The predicted hrpB gene product belongs to a family of bacterial regulators different from the previously described HrpS protein of the hrp gene cluster of Pseudomonas syringae pv. phaseolicola. Genetic evidence demonstrates that the hrpB gene product acts as a positive regulator of the expression in minimal medium of all but one of the putative transcription units of the hrp gene cluster and also controls the expression of genes located outside this cluster. We also show in this paper that the transcription of hrpB is induced in minimal medium and is partly autoregulated.

Interaction of the regulatory protein NicR1 with the promoter region of the pAO1-encoded 6-hydroxy-D-nicotine oxidase gene of Arthrobacter oxidans

The D,L-nicotine catabolism of the Gram-positive soil bacterium Arthrobacter oxidans is linked to the presence within the cells of the 160 kb catabolic plasmid pAO1. pAO1-cured cells lost the catabolic enzymes and reintroduction of pAO1 by electroporation into cured cells reestablished the nic+ phenotype. DNA band shift assays with extracts from cured and pAO1+ cells suggested that pAO1 encodes the regulatory protein NicR1. Footprint analysis revealed that two homologous palindromes (IR1 and IR2), present in the 5'-regulatory region of the 6-HDNO gene, were protected from DNase I digestion. Binding of NicR1 to the palindromes is symmetrical, co-operative, and stronger to IR1 containing the 6-HDNO gene promoter than to IR2. Site-directed mutagenesis revealed that steric constraints and sequence requirements for NicR1-binding are located exclusively in the palindromic sequences. Deletions and insertions in the interpalindromic region and in the 6-HDNO promoter -10 sequence had no effect on the binding characteristics of NicR1 to the 6-HDNO regulatory region. Acting as a repressor, NicR1 prevents binding of the E. coli RNA-polymerase to the consensus sigma 70 promoter in vitro. However, the interaction of NicR1 with the 6-HDNO promoter region in extracts of nicotine-induced cells from various growth stages did not differ from that observed with extracts of nicotine-uninduced cells.

Temperature sensing in Yersinia pestis: regulation of yopE transcription by lcrF

In Escherichia coli, a yopE::lacZ fusion was found to be regulated by temperature in the presence of the cloned BamHI G fragment of Yersinia pestis plasmid pCD1, which contains the lcrF locus. Increasing the copy number of lcrF relative to that of the yopE reporter had a negligible effect on the induction ratio (26 versus 37 degrees C) but caused large reductions in the absolute levels of yopE transcription. We localized the lcrF gene by monitoring the induction phenotype of BamHI G deletion derivatives. Sequencing revealed an open reading frame capable of encoding a protein of 30.8 kDa. A protein product of this size was detected in a T7 expression system, and LcrF-dependent yopE-specific DNA binding activity was observed. As expected, LcrF exhibited 98% homology to VirF of Yersinia enterocolitica and significant homology to the carboxy termini of other members of the AraC family of transcriptional regulatory proteins. These proteins could be divided into two classes according to function: those regulating operons involved in catabolism of carbon and energy sources and those involved in regulating virulence genes. lcrF::lacZ transcriptional fusions were constructed and analyzed in Y. pestis and E. coli. The activity of the fusions was not affected by the native pCD1 virulence plasmid, an intact lcrF gene, or temperature. Thus, induction of lcrF transcription is not essential for temperature-dependent activation of yopE transcription. A portion of LcrF was found associated with the membrane fraction in E. coli; however, pulse-chase experiments indicated that this result is an artifact of fractionation.

A general system to integrate lacZ fusions into the chromosomes of gram-negative eubacteria: regulation of the Pm promoter of the TOL plasmid studied with all controlling elements in monocopy

A new procedure is described to recombine plasmid-borne lacZ fusions into the chromosome of gram-negative eubacteria in order to study promoter activity in monocopy. The procedure is based upon the insertion into the chromosome of a target bacterium of a recombinant transposon that carries DNA sequence homology to the regions flanking lacZ fusions present in multicopy promotor-probe vectors, which can be mobilized via RP4-mediated transfer but are unable to replicate in non-enteric bacteria. Double recombination between the promoter-probe vectors and the chromosomal homology region of the transposon is genetically selected by reconstruction and expression of wild-type sequences from truncated lacZ and aadA (streptomycin/spectinomycin) resistance genes in the homology fragment and from an amber mutation carrying lacZ and aadA genes present in the plasmid vectors. The structure of desired clones is confirmed by screening for loss of the transposon-encoded kanamycin resistance marker. We have used this procedure to assemble in monocopy in Pseudomonas putida the regulatory elements controlling expression of the XylS-activated Pm promoter of the TOL catabolic plasmid pWWO. We show here that the Pm promoter undergoes a XylS-independent, strictly growth-phase-controlled activation by benzoate but not meta-toluate. In the presence of XylS, however, activation by both effectors involves a combination of growth phase-dependent and -independent controls.

Regulation of sod genes in Escherichia coli: relevance to superoxide dismutase function

This review is concerned with the effects of environmental perturbations on the expression of the two superoxide dismutase (SOD) genes in Escherichia coli (sodA, MnSOD; sodB, FeSOD). Early studies using SOD activity, showed that MnSOD levels respond to changes in oxygen tension, type of substrate, redox active compounds, iron concentration, the nature of the terminal oxidant, and the redox potential of the medium. FeSOD levels appeared nominally insensitive to these perturbations. More recent molecular genetic studies revealed that sodA expression is subject to regulation by three major regulatory systems: fur (ferric uptake regulation) and arcA arcB (aerobic respiratory control) mediate repression of sodA, while a relatively new system, soxR soxS (superoxide response), mediates activation of sodA expression. By contrast, sodB expression, which is much less studied at this time, appears to be positively activated in trans by fur. A rudimentary gene regulation model is presented which rationalizes past observations, is experimentally testable, and should serve as a guide to future research in this area.

Escherichia coli rpoA mutation which impairs transcription of positively regulated systems

The rpoA341 (phs) mutation of Escherichia coli results in decreased expression of several positively regulated operons and has been mapped to within or very near the rpoA gene encoding the alpha subunit of RNA polymerase. We have shown that plasmid-directed synthesis of the wild-type alpha subunit can complement the defective phenotypes associated with this mutation consistent with its proposed location within rpoA. This mutation was mapped by marker rescue to within a 182bp region near the 3' end of rpoA and was subsequently transferred to a plasmid by recombination in vivo. DNA sequence analysis revealed that the RpoA341 phenotype was the result of the substitution of lysine 271 by glutamate within the alpha polypeptide. We discuss this result in relation to our current understanding of the functional organization of the alpha subunit.

Two divergently transcribed genes, soxR and soxS, control a superoxide response regulon of Escherichia coli

soxR governs a superoxide response regulon that contains the genes for endonuclease IV, Mn2(+)-superoxide dismutase, and glucose 6-phosphate dehydrogenase. The soxR gene encodes a 17-kDa protein; some mutations of this gene cause constitutive overexpression of the regulon. Induction by paraquat (methyl viologen) requires both soxR and a new gene, soxS. soxS is adjacent to soxR, it encodes a 13-kDa protein, and it is required for paraquat resistance. These functions were revealed by studies in which the sequence of the 1.1-kb soxR-soxS region was determined, the 5' ends of the mRNAs were mapped, and complementation tests were performed with soxRS plasmids containing deletions of known sequence. The two genes are divergently transcribed, and the transcripts overlap. The soxS promoter is within the 85-nucleotide intergenic region, whereas the soxR promoter is within soxS. soxS mRNA increases after induction. Both protein products have possible DNA-binding (helix-turn-helix) domains. SoxR contains four cysteines (CX2CXCX5C) that might be part of a sensor region. SoxS shows 17 to 31% homology to the C-terminal portions of members of the AraC family of positive regulators.

A family of regulatory genes associated with type II restriction-modification systems

Restriction-modification systems must be regulated to avoid autorestriction and death of the host cell. An open reading frame (ORF) in the PvuII restriction-modification system appears to code for a regulatory protein from a previously unrecognized family. First, interruptions of this ORF result in a nonrestricting phenotype. Second, this ORF can restore restriction competence to such interrupted mutants in trans. Third, the predicted amino acid sequence of this ORF resembles those of known DNA-binding proteins and includes a probable helix-turn-helix motif. A survey of unattributed ORFs in 15 other type II restriction-modification systems revealed three that closely resemble the PvuII ORF. All four members of this putative regulatory gene family have a common position relative to the endonuclease genes, suggesting a common regulatory mechanism.