The DNA-binding domain of OmpR: crystal structures of a winged helix transcription factor

Genetic evidence that the alpha5 helix of the receiver domain of PhoB is involved in interdomain interactions

Two-component signaling proteins are involved in transducing environmental stimuli into intracellular signals. Information is transmitted through a phosphorylation cascade that consists of a histidine protein kinase and a response regulator protein. Generally, response regulators are made up of a receiver domain and an output domain. Phosphorylation of the receiver domain modulates the activity of the output domain. The mechanisms by which receiver domains control the activities of their respective output domains are unknown. To address this question for the PhoB protein from Escherichia coli, we have employed two separate genetic approaches, deletion analysis and domain swapping. In-frame deletions were generated within the phoB gene, and the phenotypes of the mutants were analyzed. The output domain, by itself, retained significant ability to activate transcription of the phoA gene. However, another deletion mutant that contained the C-terminal alpha-helix of the receiver domain (alpha5) in addition to the entire output domain was unable to activate transcription of phoA. This result suggests that the alpha5 helix of the receiver domain interacts with and inhibits the output domain. We also constructed two chimeric proteins that join various parts of the chemotaxis response regulator, CheY, to PhoB. A chimera that joins the N-terminal approximately 85% of CheY's receiver domain to the beta5-alpha5 loop of PhoB's receiver domain displayed phosphorylation-dependent activity. The results from both sets of experiments suggest that the regulation of PhoB involves the phosphorylation-mediated modulation of inhibitory contacts between the alpha5 helix of its unphosphorylated receiver domain and its output domain.

Lessons and questions from the structure of the Spo0A activation domain

The carboxy-terminal domain of Spo0A in Bacillus subtilis is one of the few response regulator activation domains for which the structure is known. Here, we discuss some of the mutational data and biological roles of Spo0A in light of its structure.

Two-component signal transduction

Most prokaryotic signal-transduction systems and a few eukaryotic pathways use phosphotransfer schemes involving two conserved components, a histidine protein kinase and a response regulator protein. The histidine protein kinase, which is regulated by environmental stimuli, autophosphorylates at a histidine residue, creating a high-energy phosphoryl group that is subsequently transferred to an aspartate residue in the response regulator protein. Phosphorylation induces a conformational change in the regulatory domain that results in activation of an associated domain that effects the response. The basic scheme is highly adaptable, and numerous variations have provided optimization within specific signaling systems. The domains of two-component proteins are modular and can be integrated into proteins and pathways in a variety of ways, but the core structures and activities are maintained. Thus detailed analyses of a relatively small number of representative proteins provide a foundation for understanding this large family of signaling proteins.

The critical role of DNA in the equilibrium between OmpR and phosphorylated OmpR mediated by EnvZ in Escherichia coli

Escherichia coli modulates its porin expression through a histidine kinase, EnvZ, and its cognate response regulator, OmpR. EnvZ is a bifunctional enzyme that possesses both OmpR kinase and phosphorylated OmpR (OmpR-P) phosphatase activities and thus controls the cellular level of OmpR-P. In an in vitro-assay system, the addition of OmpR to the reaction mixture consisting of the cytoplasmic domain of EnvZ (EnvZc) and ATP produces a barely detectable amount of OmpR-P because of the dual activities of EnvZ. Here we report that DNA fragments containing the upstream promoter regions of the porin genes (ompF and ompC) can shift the equilibrium between OmpR and OmpR-P dramatically toward OmpR-P. Among the four reactions occurring in the mixture, only the EnvZ phosphatase activity was inhibited severely by the specific DNA, in contrast to the previous report by Kenney and her associates that DNA stimulates OmpR phosphorylation by EnvZ [Ames, S. K., Frankema, N. & Kenney, L. J. (1999) Proc. Natl. Acad. Sci. USA 96, 11792-11797]. The autophosphorylation of EnvZc and the phosphotransfer from phosphorylated EnvZc to OmpR were not affected by DNA, whereas the autodephosphorylation of OmpR-P was inhibited slightly. We propose that the apparent inhibitory effect of DNA on the EnvZ phosphatase function is caused by sequestrating OmpR-P from the reaction as a result of OmpR-P binding to DNA.

The critical role of DNA in the equilibrium between OmpR and phosphorylated OmpR mediated by EnvZ in Escherichia coli

Escherichia coli modulates its porin expression through a histidine kinase, EnvZ, and its cognate response regulator, OmpR. EnvZ is a bifunctional enzyme that possesses both OmpR kinase and phosphorylated OmpR (OmpR-P) phosphatase activities and thus controls the cellular level of OmpR-P. In an in vitro-assay system, the addition of OmpR to the reaction mixture consisting of the cytoplasmic domain of EnvZ (EnvZc) and ATP produces a barely detectable amount of OmpR-P because of the dual activities of EnvZ. Here we report that DNA fragments containing the upstream promoter regions of the porin genes (ompF and ompC) can shift the equilibrium between OmpR and OmpR-P dramatically toward OmpR-P. Among the four reactions occurring in the mixture, only the EnvZ phosphatase activity was inhibited severely by the specific DNA, in contrast to the previous report by Kenney and her associates that DNA stimulates OmpR phosphorylation by EnvZ [Ames, S. K., Frankema, N. & Kenney, L. J. (1999) Proc. Natl. Acad. Sci. USA 96, 11792-11797]. The autophosphorylation of EnvZc and the phosphotransfer from phosphorylated EnvZc to OmpR were not affected by DNA, whereas the autodephosphorylation of OmpR-P was inhibited slightly. We propose that the apparent inhibitory effect of DNA on the EnvZ phosphatase function is caused by sequestrating OmpR-P from the reaction as a result of OmpR-P binding to DNA.

DNA-binding of phenylalanyl-tRNA synthetase is accompanied by loop formation of the double-stranded DNA

The phenylalanyl-tRNA synthetase (FRS) from Thermus thermophilus has previously been shown to bind DNA. We demonstrate that the "winged" helix-turn-helix motifs in the duplicate domains B5 are the relevant structural elements for this DNA-binding property. By altering particular amino acids in the "wing", the affinity of the FRS to DNA was significantly reduced. Based on experimental data, which indicate that the FRS prefers a certain DNA structure rather than a particular consensus sequence, we propose a novel loop model for the DNA-binding mode of the FRS. In our model we assume that two segments of the same DNA molecule are bound simultaneously by both B5 domains and are aligned in parallel, while the intervening DNA forms a loop. Due to the limited flexibility of the DNA, loop formation is only possible if the respective intervening DNA stretch exceeds a certain length. Several lines of evidence support this model. (1) We demonstrate by gel retardation assays that the DNA requires a minimal number of ca 80 base-pairs to be bound by the FRS. (2) In the presence of the FRS, DNA longer than ca 80 base-pairs has a significantly increased DNase I accessibility. This agrees well with its known preferential cleavage at positions where the minor grove is on the outside of looped-out DNA molecules. (3) The initial cleavage by DNase I of >80 bp long DNA occurs in the middle of the fragment. In a looped molecule this is the position with the highest accessibility to DNase I. The function of the FRS related to DNA binding is still unknown. Since the FRS exists in the nucleus of rapidly growing mammalian cells, and protein-induced DNA bending or looping contributes to several transcription, replication, and recombination systems in both prokaryotes and eukaryotes, it is likely that the FRS, in addition to its aminoacylation function, influences common cellular processes via DNA binding.

Evolution of two-component signal transduction

Two-component signal transduction (TCST) systems are the principal means for coordinating responses to environmental changes in bacteria as well as some plants, fungi, protozoa, and archaea. These systems typically consist of a receptor histidine kinase, which reacts to an extracellular signal by phosphorylating a cytoplasmic response regulator, causing a change in cellular behavior. Although several model systems, including sporulation and chemotaxis, have been extensively studied, the evolutionary relationships between specific TCST systems are not well understood, and the ancestry of the signal transduction components is unclear. Phylogenetic trees of TCST components from 14 complete and 6 partial genomes, containing 183 histidine kinases and 220 response regulators, were constructed using distance methods. The trees showed extensive congruence in the positions of 11 recognizable phylogenetic clusters. Eukaryotic sequences were found almost exclusively in one cluster, which also showed the greatest extent of domain variability in its component proteins, and archaeal sequences mainly formed species-specific clusters. Three clusters in different parts of the kinase tree contained proteins with serine-phosphorylating activity. All kinases were found to be monophyletic with respect to other members of their superfamily, such as type II topoisomerases and Hsp90. Structural analysis further revealed significant similarity to the ATP-binding domain of eukaryotic protein kinases. TCST systems are of bacterial origin and radiated into archaea and eukaryotes by lateral gene transfer. Their components show extensive coevolution, suggesting that recombination has not been a major factor in their differentiation. Although histidine kinase activity is prevalent, serine kinases have evolved multiple times independently within this family, accompanied by a loss of the cognate response regulator(s). The structural and functional similarity between TCST kinases and eukaryotic protein kinases raises the possibility of a distant evolutionary relationship.

Identification by gene deletion analysis of a regulator, VmsR, that controls virginiamycin biosynthesis in Streptomyces virginiae

Virginiae butanolide (VB)-BarA of Streptomyces virginiae is one of the newly discovered pairs of a butyrolactone autoregulator and a corresponding receptor protein of Streptomyces species and regulates the production of the antibiotic virginiamycin (VM) in S. virginiae. The gene vmsR was found to be situated 4.7 kbp upstream of the barA gene, which encodes the VB-specific receptor. The vmsR product was predicted to be a regulator of VM biosynthesis based on its high homology to some Streptomyces pathway-specific transcriptional regulators for the biosynthetic gene clusters of polyketide antibiotics, such as Streptomyces peucetius DnrI (47.5% identity, 84. 3% similarity), which controls daunorubicin biosynthesis. A vmsR deletion mutant was created by homologous recombination. Neither virginiamycin M(1) nor virginiamycin S was produced in the vmsR mutant, while amounts of VB and BarA similar to those produced in the wild-type strain were detected. Reverse transcription-PCR analyses confirmed that the vmsR deletion had no deleterious effects on the transcription of the vmsR-surrounding genes, indicating that VmsR is a positive regulator of VM biosynthesis in S. virginiae.

The trans-activation domain of the sporulation response regulator Spo0A revealed by X-ray crystallography

Sporulation in Bacillus involves the induction of scores of genes in a temporally and spatially co-ordinated programme of cell development. Its initiation is under the control of an expanded two-component signal transduction system termed a phosphorelay. The master control element in the decision to sporulate is the response regulator, Spo0A, which comprises a receiver or phosphoacceptor domain and an effector or transcription activation domain. The receiver domain of Spo0A shares sequence similarity with numerous response regulators, and its structure has been determined in phosphorylated and unphosphorylated forms. However, the effector domain (C-Spo0A) has no detectable sequence similarity to any other protein, and this lack of structural information is an obstacle to understanding how DNA binding and transcription activation are controlled by phosphorylation in Spo0A. Here, we report the crystal structure of C-Spo0A from Bacillus stearothermophilus revealing a single alpha-helical domain comprising six alpha-helices in an unprecedented fold. The structure contains a helix-turn-helix as part of a three alpha-helical bundle reminiscent of the catabolite gene activator protein (CAP), suggesting a mechanism for DNA binding. The residues implicated in forming the sigmaA-activating region clearly cluster in a flexible segment of the polypeptide on the opposite side of the structure from that predicted to interact with DNA. The structural results are discussed in the context of the rich array of existing mutational data.

The Vibrio cholerae ToxR/TcpP/ToxT virulence cascade: distinct roles for two membrane-localized transcriptional activators on a single promoter

ToxR is required in Vibrio cholerae for transcriptional activation of the toxT gene, the protein product of which activates numerous genes involved in virulence. Although ToxR cannot activate the toxT promoter in Escherichia coli, the products of the tcpPH operon are shown here to activate the toxT promoter, and co-expression with ToxRS enhances activation. An identical pattern was seen in a DeltatcpPDeltatoxR strain of V. cholerae when TcpPH or ToxRS was expressed from plasmids. Although overexpression of the TcpP/H proteins in V. cholerae partially complemented both a DeltatoxR strain and a DeltatcpPDeltatoxR double mutant for toxin production and toxT-lacZ activation, the presence of ToxR greatly increased their expression. Analysis of a toxT-lacZ promoter deletion series demonstrated that TcpP was able to interact functionally with the toxT promoter downstream of the ToxR binding site. This was confirmed using electrophoretic mobility shift assays of this toxT promoter deletion series and DNase I footprinting analysis, which showed that TcpP interacts with the promoter region from -51 to -32, whereas ToxR protected a region from -100 to -69. In addition, membranes containing endogenous levels of ToxR bound more readily to the toxT promoter than did membranes containing only TcpP. Characterization of a number of tcpP substitution mutants revealed one derivative (TcpP-H93L) that, when overexpressed, was markedly defective for toxT activation, cholera toxin and TcpA (toxin co-regulated pilus) production and DNA binding; however, toxT activation by TcpP-H93L was restored in the presence of ToxR, suggesting that ToxR can provide the promoter recognition function for toxT activation. Two additional mutant derivatives, TcpP-W68L and TcpP-R86A, failed to activate toxT or direct toxin and TcpA production in the presence or absence of ToxR. Both TcpP-W68L and TcpP-R86A, like TcpP-H93L, were defective for DNA binding. Finally, a ToxR mutant derivative, ToxR-G80S, served to separate the different roles of ToxR on different promoters. Although ToxR-G80S was inefficient at activating the ompU promoter in V. cholerae (ompU encodes an outer membrane porin regulated by ToxR), it was fully capable of activating the toxT promoter. These data suggest that ToxR is not a direct activator in the toxT expression system but, instead, enhances the activity of TcpP, perhaps by recruiting it to the toxT promoter under conditions in which expression levels of TcpP are too low for it to activate toxT efficiently on its own.

Inhibitors of bacterial two-component signalling systems

Bacterial two-component regulatory systems (TCS) play a pivotal role in the process of infection. These signal transduction systems enable bacterial pathogens to mount an adaptive response and cope with diverse environmental stresses, including nutrient deprivation, antibiotic onslaught and phagocytosis. Interest in these systems as novel bacterial targets has been rekindled by the recent discovery of several essential systems in important Gram-positive and Gram-negative pathogens. Several series of TCS inhibitors derived from broad screening approaches have been reported in the literature, however, most appear to suffer from poor selectivity, excessive protein binding and/or limited bioavailability. Consequently, pharmaceutical chemists have turned to alternate strategies, such as the design of substrate-based inhibitors, the generation of combinatorial libraries and the isolation of natural products, to identify inhibitors with more desirable properties. Recent structural studies of the histidine protein kinase and response regulator proteins that constitute TCS may provide a foundation for a structure-based design approach to TCS inhibitors.

ResD signal transduction regulator of aerobic respiration in Bacillus subtilis: ctaA promoter regulation

A two-component signal transduction system composed of a sensor kinase, ResE, and a response regulator, ResD, encoded by resD and resE genes of the res operon (resABCDE), has a regulatory role in both aerobic and anaerobic respiration. In terms of aerobic respiration, resD functions upstream of ctaA, a gene required for haem A biogenesis and hence for the synthesis of haem A-containing cytochrome terminal oxidases. Although ResD is probably a transcription factor, there was no direct evidence that ResD protein, either phosphorylated or unphosphorylated, interacts directly with regulatory regions of ResD-controlled genes. Here, we report the overexpression and purification of ResD and ResE and their role in gene activation. ResD can be phosphorylated by ResE in vitro and is a monomer in solution in either the phosphorylated or unphosphorylated state. The binding activity of ResD to the ctaA promoter was examined by gel shift assays and DNase I footprinting assays. DNase I footprinting showed both unphosphorylated and phosphorylated ResD binding to the ctaA promoter and showed that there are three binding sites (A1, A2 and A3), two (A1 and A2) upstream of the -35 promoter region and one (A3) downstream of the -10 of the promoter. The role of each site in ctaA promoter activity and ResD binding was characterized using deletion analysis, followed by the DNase I footprinting and in vivo transcription assays of promoter-lacZ fusions. Our results showed that the concentration of ResD required to bind at each site is different and that ResD binding at the A1 site is independent of the other two ResD binding sites, but that the concentration of ResD approximately P required to protect site A2 is reduced when site A3 is present. In vivo transcription assays from promoter-lacZ fusion constructs showed that DNA containing ResD-binding site A2 was essential for promoter activity and that promoter constructs containing both binding sites A2 and A3 were sufficient for full promoter activity.

Phosphorylated PmrA interacts with the promoter region of ugd in Salmonella enterica serovar typhimurium

The Salmonella PmrA-PmrB system controls the expression of genes necessary for polymyxin B resistance. Four loci were previously identified as part of the regulon, and interaction of PmrA with the promoter region of three of them was observed. Here we characterized the interaction of PmrA with the promoter region of ugd, previously suggested to be regulated indirectly by PmrA. Our results indicate that PmrA controls the expression of ugd by interacting with a specific sequence in the promoter region of this gene.

A single amino acid substitution in the C terminus of OmpR alters DNA recognition and phosphorylation

In bacteria and lower eukaryotes, adaptation to changes in the environment is often mediated by two-component regulatory systems. Such systems provide the basis for chemotaxis, nitrogen and phosphate regulation and adaptation to osmotic stress, for example. In Escherichia coli, the sensor kinase EnvZ detects a change in the osmotic environment and phosphorylates the response regulator OmpR. Phospho-OmpR binds to the regulatory regions of the porin genes ompF and ompC, and alters their expression. Recent evidence suggests that OmpR functions as a global regulator, regulating additional genes besides the porin genes. In this study, we have characterized a previously isolated OmpR2 mutant (V203M) that constitutively activates ompF and fails to express ompC. Because the substitution was located in the C-terminal DNA-binding domain, it had been assumed that the substitution would not affect phosphorylation of the N-terminal domain of OmpR. Our results indicate that this substitution completely eliminates phosphorylation by a small phosphate donor, acetyl phosphate, but not phosphorylation by the kinase EnvZ. The mutant OmpR has altered dephosphorylation kinetics and altered binding affinities to both ompF and ompC sites compared to the wild-type. Thus, a single amino acid substitution in the C-terminal DNA-binding domain has dramatic effects on the N-terminal phosphorylation domain. Most strikingly, we have identified a single base change in the OmpR binding site of ompC that restores high-affinity binding activity by the mutant. We interpret our results in the context of a model for porin gene expression.

Molecular characterization of two-component systems of Helicobacter pylori

Two-component systems are frequently involved in the adaptation of bacteria to changing environmental conditions at the level of transcriptional regulation. Here we report the characterization of members of the two-component systems of the gastric pathogen Helicobacter pylori deduced from the genome sequence of strain 26695. We demonstrate that the response regulators HP166, HP1043, and HP1021 have essential functions, as disruption of the corresponding genes is lethal for the bacteria, irrespective of the fact that HP1043 and HP1021 have nonconserved substitutions in crucial amino acids of their receiver domains. An analysis of the in vitro phosphorylation properties of the two-component proteins demonstrates that HP244-HP703 and HP165-HP166 are cognate histidine kinase-response regulator pairs. Furthermore, we provide evidence that the variability of the histidine kinase HP165 caused by a poly(C) tract of variable length close to the 3' end of open reading frame 165/164 does not interfere with the kinase activity of the transmitter domain of HP165.

Structure of the central core domain of TFIIEbeta with a novel double-stranded DNA-binding surface

Human general transcription factor TFIIE consists of two subunits, TFIIEalpha and TFIIEbeta. Recently, TFIIEbeta has been found to bind to the region where the promoter starts to open to be single-stranded upon transcription initiation by RNA polymerase II. Here, the central core domain of human TFIIEbeta (TFIIEbetac) has been identified by a limited proteolysis. This solution structure has been determined by NMR. It consists of three helices with a beta hairpin at the C-terminus, resembling the winged helix proteins. However, TFIIEbetac shows a novel double-stranded DNA-binding activity where the DNA-binding surface locates on the opposite side to the previously reported winged helix motif by forming a positively charged furrow. A model will be proposed that TFIIE stabilizes the preinitiation complex by binding not only to the general transcription factors together with RNA polymerase II but also to the promoter DNA, where double-stranded DNA starts to open to be single-stranded upon activation of the preinitiation complex.

Structural comparison of the PhoB and OmpR DNA-binding/transactivation domains and the arrangement of PhoB molecules on the phosphate box

PhoB is a transcriptional activator that binds to the phosphate box in the promoters of the phosphate genes of Escherichia coli. PhoB contains two functional domains, an N-terminal phosphorylation domain and a C-terminal DNA-binding/transactivation domain. Here, the three-dimensional structure of the DNA-binding/transactivation domain has been determined by NMR. It consists of an N-terminal four-stranded beta-sheet, a central three helical bundle and a C-terminal beta-hairpin. The second and third helices form a helix-turn-helix (HTH) variant containing a longer turn than the corresponding turn of the classical HTH motif. The overall architecture is very close to that of the OmpR DNA-binding/transactivation domain, however, the conformation of the long turn region of PhoB, a putative interaction site for the RNA polymerase sigma subunit, is entirely different from that of the corresponding turn of OmpR, which interacts with the alpha subunit. In addition, the third helix of PhoB is three amino acid residues longer than the corresponding helix of OmpR. The binding site of PhoB is a TGTCA sequence and the phospahte box contains the two binding sites. NMR studies of the complexes of the PhoB DNA-binding/transactivation domain bound to several different DNA molecules have revealed that two PhoB molecules bind in a tandem array on the phosphate box. In each complex of PhoB the third helix of the DNA-binding/transactivation domain is likely to recognize the TGTCA sequence from the major groove of DNA and the C-terminal beta-hairpin contacts on the minor groove of the 3' site out of the TGTCA sequence in a non-specific manner. The long turn region facing outward is likely to interact with the sigma subunit.

A genomic analysis of two-component signal transduction in Streptococcus pneumoniae

A genomics-based approach was used to identify the entire gene complement of putative two-component signal transduction systems (TCSTSs) in Streptococcus pneumoniae. A total of 14 open reading frames (ORFs) were identified as putative response regulators, 13 of which were adjacent to genes encoding probable histidine kinases. Both the histidine kinase and response regulator proteins were categorized into subfamilies on the basis of phylogeny. Through a systematic programme of mutagenesis, the importance of each novel TCSTS was determined with respect to viability and pathogenicity. One TCSTS was identified that was essential for the growth of S. pneumoniaeThis locus was highly homologous to the yycFG gene pair encoding the essential response regulator/histidine kinase proteins identified in Bacillus subtilis and Staphylococcus aureus. Separate deletions of eight other loci led in each case to a dramatic attenuation of growth in a mouse respiratory tract infection model, suggesting that these signal transduction systems are important for the in vivo adaptation and pathogenesis of S. pneumoniae. The identification of conserved TCSTSs important for both pathogenicity and viability in a Gram-positive pathogen highlights the potential of two-component signal transduction as a multicomponent target for antibacterial drug discovery.

C-terminal DNA binding stimulates N-terminal phosphorylation of the outer membrane protein regulator OmpR from Escherichia coli

Expression of the porin genes of Escherichia coli is regulated in part by the osmolarity of the growth medium. The process is controlled by the histidine kinase EnvZ and the response regulator OmpR. We have previously shown that phosphorylation of OmpR increases its affinity for the upstream regulatory regions of ompF and ompC. We now report that, in the presence of DNA, there is a dramatic stimulation in the level of phospho-OmpR. This effect is independent of the source of phosphorylation, i.e., stimulation of phosphorylation is observed with a small phosphorylating agent such as acetyl phosphate or with protein-catalyzed phosphorylation by the kinase EnvZ. The dephosphorylation rate of phospho-OmpR is affected only slightly by the presence of DNA; thus, the increased level is largely caused by an increased rate of phosphorylation. Stimulation of phosphorylation requires specific binding of DNA by OmpR. Occupancy of the DNA binding domain exposes a trypsin cleavage site in the linker, which connects the phosphorylation domain with the DNA binding domain. Our results indicate that when DNA binds in the C terminus, it enhances phosphorylation in the N terminus, and the linker undergoes a conformational change. A generalized mechanism involving a four-state model for response regulators is proposed.

Site-directed mutagenesis of the response regulator DmsR for the dmsCBA operon expression in Rhodobacter sphaeroides f. sp. Denitrificans: An essential residue of proline-130 in the linker

DmsR protein is a member of the OmpR response regulator subfamily that activates the transcription of the dmsCBA operon in Rhodobacter sphaeroides f. sp. denitrificans. By site-directed mutagenesis some functional amino acid residues were investigated in DmsR, which consists of the N-terminal regulatory and the C-terminal DNA-binding domains and the linker connecting the two domains. The substitution of P130S in the linker caused decreases of both DNA-binding and transcriptional activator activities. Introducing additional substitutions of R129P or D131P to the DmsR-P130S derivative recovered both activities, demonstrating necessity of proline residue at one of the positions 129-131 in the linker. Substitutions of D12A, D55A, and K104M, at residues conserved in the phosphorylation region, caused no production of DMSO reductase, but retained DNA-binding ability, suggesting that unphosphorylated DmsR also has high affinity to its target nucleotide sequence of DNA. Substitutions in the C-terminal domain suggested the presence of a winged helix-turn-helix structure observed in the DNA-binding domain of the Escherichia coli OmpR.

Emergence of vancomycin tolerance in Streptococcus pneumoniae

Streptococcus pneumoniae, the pneumococcus, is the most common cause of sepsis and meningitis. Multiple-antibiotic-resistant strains are widespread, and vancomycin is the antibiotic of last resort. Emergence of vancomycin resistance in this community-acquired bacterium would be catastrophic. Antibiotic tolerance, the ability of bacteria to survive but not grow in the presence of antibiotics, is a precursor phenotype to resistance. Here we show that loss of function of the VncS histidine kinase of a two-component sensor-regulator system in S. pneumoniae produced tolerance to vancomycin and other classes of antibiotic. Bacterial two-component systems monitor environmental parameters through a sensor histidine-kinase/phosphatase, which phosphorylates/dephosphorylates a response regulator that in turn mediates changes in gene expression. These results indicate that signal transduction is critical for the bactericidal activity of antibiotics. Experimental meningitis caused by the vncS mutant failed to respond to vancomycin. Clinical isolates tolerant to vancomycin were identified and DNA sequencing revealed nucleotide alterations in vncS. We conclude that broad antibiotic tolerance of S. pneumoniae has emerged in the community by a molecular mechanism that eliminates sensitivity to the current cornerstone of therapy, vancomycin.

Mutational analysis of the phoD promoter in Bacillus subtilis: implications for PhoP binding and promoter activation of Pho regulon promoters

The PhoP-PhoR two-component regulatory system controls the phosphate deficiency response in B. subtilis. A number of Pho regulon genes which require PhoP approximately P for activation or repression have been identified. The studies reported here were initiated to understand the PhoP-DNA interaction necessary for Pho promoter regulation. The regulatory region of phoD was characterized in detail using oligo-directed mutagenesis, DNase I footprinting, and in vivo transcription assays. These data reveal basic principles of PhoP binding relevant to PhoP's interaction with other Pho regulon promoters. Our results show that: (i) a dimer of PhoP approximately P is able to bind two consensus repeats in a stable fashion; (ii) PhoP binding is highly cooperative within the core promoter region, which is located from -66 to -17 on the coding strand and contains four TT(A/T/C)ACA-like repeats; (iii) specific bases comprising the TT(A/T/C)ACA consensus are essential for transcriptional activation, but the specific base pairs of the intervening sequences separating the consensus repeats are not important for either PhoP binding or promoter activation; (iv) the spacing between two consensus repeats within a putative dimer binding site in the core region is important for both PhoP binding and promoter activation; (v) the exact spacing between two dimer binding sites within the core region is important for promoter activation but less so for PhoP binding affinity, as long as the repeats are on the same face of the helix; and (vi) the 5' secondary binding region is important for coordinated PhoP binding to the core binding region, making it nearly essential for promoter activation.

The high-resolution crystal structure of the molybdate-dependent transcriptional regulator (ModE) from Escherichia coli: a novel combination of domain folds

The molybdate-dependent transcriptional regulator (ModE) from Escherichia coli functions as a sensor of molybdate concentration and a regulator for transcription of operons involved in the uptake and utilization of the essential element, molybdenum. We have determined the structure of ModE using multi-wavelength anomalous dispersion. Selenomethionyl and native ModE models are refined to 1. 75 and 2.1 A, respectively and describe the architecture and structural detail of a complete transcriptional regulator. ModE is a homodimer and each subunit comprises N- and C-terminal domains. The N-terminal domain carries a winged helix-turn-helix motif for binding to DNA and is primarily responsible for ModE dimerization. The C-terminal domain contains the molybdate-binding site and residues implicated in binding the oxyanion are identified. This domain is divided into sub-domains a and b which have similar folds, although the organization of secondary structure elements varies. The sub-domain fold is related to the oligomer binding-fold and similar to that of the subunits of several toxins which are involved in extensive protein-protein interactions. This suggests a role for the C-terminal domain in the formation of the ModE-protein-DNA complexes necessary to regulate transcription. Modelling of ModE interacting with DNA suggests that a large distortion of DNA is not necessary for complex formation.

Signalling pathways in two-component phosphorelay systems

Two-component systems are characterized by phosphotransfer reactions involving histidine and aspartate residues in highly conserved signalling domains. Although the basic principles of signal transduction by these systems have been elucidated, several important aspects, such as their integration into more complex cellular regulatory networks and the molecular basis of the specificity of signal transduction, remain unknown.

Identification of a Streptococcus pneumoniae gene locus encoding proteins of an ABC phosphate transporter and a two-component regulatory system

The Escherichia coli Pst system belongs to the family of ABC transporters. It is part of a phosphate (PHO) regulon which is regulated by extracellular phosphate. Under conditions of phosphate limitation, the response regulator PhoB is phosphorylated by the histidine kinase PhoR and binds to promoters that share a consensus PHO box. Under conditions of phosphate excess, PhoR, Pst, and PhoU downregulate the PHO regulon. Screening of a library of pneumococcal mutants with defects in exported proteins revealed a putative two-component regulatory system, PnpR-PnpS, and a downstream ABC transporter, similar to the Pst system in E. coli including a gene encoding a PhoU protein. Similar to E. coli, mutagenesis of the ATP-binding cassette gene, pstB, resulted in decreased uptake of phosphate. The effects of the loss of the pneumococcal Pst system extended to decreased transformation and lysis. Withdrawal of phosphate led to transformation deficiency in the parent strain R6x but not to penicillin tolerance, suggesting that reduced bacterial death was independent of phosphate. None of these phenotypes was observed in the pneumococcal loss-of-function mutant phoU. By using a lacZ reporter construct, it was demonstrated that expression of the two-component regulatory system PnpR-PnpS was not influenced by different concentrations of phosphate. These results suggest a more complex role of the Pst system in pneumococcal physiology than in that of E. coli.

Orientation of OmpR monomers within an OmpR:DNA complex determined by DNA affinity cleaving

Escherichia coli OmpR is a transcription factor that regulates the differential expression of the porin genes ompF and ompC. Phosphorylated OmpR binds as a dimer to a 20-bp region of DNA consisting of two tandemly arranged 10-bp half-sites. Expression of the ompF gene is achieved by the hierarchical occupation of three adjacent 20-bp binding sites, designated F1, F2, and F3 and a distally located site, F4. Despite genetic, biochemical, and structural studies, specific details of the interaction between phosphorylated OmpR and the DNA remain unknown. We have linked the DNA cleaving moiety o-phenanthroline-copper to eight different sites within the DNA binding domain of OmpR in order to determine the orientation of the two OmpR monomers in the OmpR:F1 complex. Five of the resulting conjugates exhibited DNA cleaving activity, and four of these yielded patterns that could be used to construct a model of the OmpR:F1 complex. We propose that OmpR binds asymmetrically to the F1 site as a tandemly arranged dimer with each monomer having its recognition helix in the major groove. The N-terminal end of the recognition helix is promoter-proximal and flanked by "wings" W1 and W2 positioned proximally and distally, respectively, to the transcription start site of ompF. We further propose that the C-terminal end of the recognition helix makes the most extensive contacts with DNA and predict bases within the F1 site that are sufficiently close to be contacted by the recognition helix.

Three-dimensional crystal structure of the transcription factor PhoB receiver domain

PhoB is the response regulator of the two-component signal transduction system activated under phosphate starvation conditions. This protein is a transcription factor that activates more than 30 genes of the pho regulon and consists of two domains: a DNA binding domain and a dimerization domain, the latter being homologous to the receiver domain described for two-component response regulators. Activation by phosphorylation induces dimerization of the protein and the consequent binding to the DNA direct repeat pho box, where it promotes the binding of RNA polymerase. In the absence of phosphorylation, the activating dimerization process can be mimicked by deletion of the DNA binding domain. The three-dimensional crystal structure of the receiver domain of PhoB from Escherichia coli has been solved by multiple anomalous diffraction using a gold derivative obtained by co-crystallization, and refined using data to 1.9 A resolution. The crystal structure reveals an alpha/beta doubly wound fold, similar to other known receivers, the most conspicuous difference being the displacement of helix alpha4 towards its N terminus. The active site includes the acidic triad Asp53 (the site of phosphorylation), Asp10 and Glu9. Lys105, from loop beta5alpha5, and Glu88, from helix alpha4, interact with Asp53 via an H-bond and a water bridge, respectively. In the asymmetric unit of the crystal there are two molecules linked by a complementary hydrophobic surface, which involves helix alpha1, loop beta5alpha5 and the N terminus of helix alpha5, and is connected to the active site through the fully conserved residue Lys105 from loop beta5alpha5. The possibility that this surface is the functional surface used for the activating dimerization is discussed.

The mithramycin gene cluster of Streptomyces argillaceus contains a positive regulatory gene and two repeated DNA sequences that are located at both ends of the cluster

Sequencing of a 4.3-kb DNA region from the chromosome of Streptomyces argillaceus, a mithramycin producer, revealed the presence of two open reading frames (ORFs). The first one (orfA) codes for a protein that resembles several transport proteins. The second one (mtmR) codes for a protein similar to positive regulators involved in antibiotic biosynthesis (DnrI, SnoA, ActII-orf4, CcaR, and RedD) belonging to the Streptomyces antibiotic regulatory protein (SARP) family. Both ORFs are separated by a 1.9-kb, apparently noncoding region. Replacement of the mtmR region by an antibiotic resistance cassette completely abolished mithramycin biosynthesis. Expression of mtmR in a high-copy-number vector in S. argillaceus caused a 16-fold increase in mithramycin production. The mtmR gene restored actinorhodin production in Streptomyces coelicolor JF1 mutant, in which the actinorhodin-specific activator ActII-orf4 is inactive, and also stimulated actinorhodin production by Streptomyces lividans TK21. A 241-bp region located 1.9 kb upstream of mtmR was found to be repeated approximately 50 kb downstream of mtmR at the other end of the mithramycin gene cluster. A model to explain a possible route for the acquisition of the mithramycin gene cluster by S. argillaceus is proposed.

Analysis of the conserved acidic residues in the regulatory domain of PhoB

The PhoB protein from Escherichia coli is a member of the two-component signal transduction pathway that controls an adaptive response to limiting phosphate. Activation involves its phosphorylation on a conserved aspartate. Site-directed mutations were introduced at conserved acidic residues. The E9D, D10E, D10N, E11A, E11D and E11Q mutants were each able to induce alkaline phosphatase under low phosphate growth conditions whereas the E9A, D10A, D53A, D53E and D53N could not. The E9Q mutant was constitutively active. Phosphorylation assays showed that only the E9D, E11A, E11Q and E11D mutants were phosphorylated by acetyl phosphate. Most mutants also displayed defects in magnesium binding.

Hierarchical and co-operative binding of OmpR to a fusion construct containing the ompC and ompF upstream regulatory sequences of Escherichia coli

BACKGROUND

OmpR is a transcription factor that regulates the expression of the porin genes ompF and ompC in Escherichia coli. The phosphorylation state of OmpR, directed by the osmosensor EnvZ, determines its ability to bind to the upstream regulatory regions of these genes, a total of 14 phospho-OmpR binding sites. While it has been possible to study the stoichiometry and hierarchy of the OmpR-DNA interaction in the upstream regions of ompF and ompC, their disunited location on the bacterial chromosome has made it difficult to compare the individual binding affinities of respective sites.

RESULTS

Using 1,10-phenanthroline-Cu+ footprinting on a fused construct containing both the ompF and ompC upstream regulatory sequences, and gel shift experiments on oligomers corresponding to individual sites, we have established a comparative hierarchy for OmpR binding, as F1, C1 > F2, F3 > C2 > C3. In addition, the binding patterns reveal an apparent co-operative relationship between OmpR molecules bound at several upstream motifs. Densitometric analyses of the footprinted regions provide support for these observations. Mutational analysis of this construct reveals that the alteration of a conserved cytidine in the F1 motif (-86) causes a loss of OmpR affinity and disrupts hierarchical OmpR-binding in the entire ompF region.

CONCLUSIONS

The present results provide a unique view of the OmpR interaction with the two respective promoters, ompF and ompC, and an insight into the question of how the expression of ompF and ompC are reciprocally regulated by medium osmolarity.

A two-component signal transduction system essential for growth of Bacillus subtilis: implications for anti-infective therapy

A two-component signal transduction system encoded by the yycF and yycG genes is part of an operon containing three genes, yycH, yycI, and yycJ, with no known function and a gene, yycK, coding for an HtrA-like protease. This operon was transcribed during growth, and its transcription shut down as the cells approached stationary phase. This decreased transcription was not Spo0A dependent. The HtrA protease gene was separately controlled during sporulation from a sigmaG promoter. Studies using insertional inactivation plasmids revealed that neither yycF nor yycG could be inactivated, whereas the other genes were inactivated without loss of viability. A temperature-sensitive YycF response regulator mutant was isolated and shown to have an H215P mutation in a putative DNA-binding domain which is closely related to the OmpR family of response regulators. At the nonpermissive temperature, cultures of the mutant strain stopped growth within 30 min, and this was followed by a decrease in optical density. Microscopically, many of the cells appeared to retain their structure while being empty of their contents. The essential processes regulated by this two-component system remain unknown. A search of the genome databases revealed YycF, YycG, and YycJ homologues encoded by three linked genes in Streptococcus pyogenes. The high level of identity of these proteins (71% for YycF) suggests that this system may play a similar role in gram-positive pathogens.

Two-component signal-transducing systems involved in stress responses and vancomycin susceptibility in Lactobacillus sakei

Fragments of five rrp genes encoding response regulators (RRs) in Lactobacillus sakei were amplified by PCR using degenerate oligonucleotide primers. The five rrp genes were part of distinct loci that also comprised hpk genes encoding histidine protein kinases (HPKs). The putative RRs belonged to the OmpR-PhoB subclass of response regulators that consist of N-terminal receiver and C-terminal DNA-binding domains. The putative HPKs were members of the EnvZ-NarX family of orthodox histidine protein kinases which possess two transmembrane segments in a non-conserved N-terminal domain and a C-terminal cytoplasmic kinase domain. Insertional inactivation of the rrp genes indicated that the RRs are implicated in susceptibility to the glycopeptide antibiotic vancomycin, and to extreme pH, temperature and oxidative conditions.

Relative binding affinities of OmpR and OmpR-phosphate at the ompF and ompC regulatory sites

In Escherichia coli, porin gene expression is regulated, in part, by the two-component regulatory system consisting of the two proteins EnvZ and OmpR. EnvZ is an integral inner membrane protein that is phosphorylated by cytoplasmic ATP on a histidine residue. EnvZ modulates the activity of OmpR by phosphorylation and dephosphorylation. Phospho-OmpR (OmpR-P) binds to the porin genes ompF and ompC to regulate their expression. The simple affinity model predicts that as the concentration of OmpR-P increases, initially high-affinity binding sites on ompF are filled. Then binding sites of lower affinity on ompF and ompC are occupied and this ordered binding accounts for the differential expression of the porin genes. We demonstrate that acetyl phosphate phosphorylates OmpR at aspartate 55, the same residue phosphorylated by the kinase EnvZ. Quantification of the level of OmpR-P by HPLC and direct measurement of the binding affinities enabled us to test the affinity model. Our results indicate that phosphorylation dramatically increases the affinity of OmpR for its binding sites (greater than tenfold). We also show that the affinities of OmpR-P for F1 and C1 binding sites are not sufficiently different to provide a strong basis for discrimination. The consequences of these observations for the simple affinity model are considered.

A response regulator of cyanobacteria integrates diverse environmental signals and is critical for survival under extreme conditions

Microorganisms must sense their environment and rapidly tune their metabolism to ambient conditions to efficiently use available resources. We have identified a gene encoding a response regulator, NblR, that complements a cyanobacterial mutant unable to degrade its light-harvesting complex (phycobilisome), in response to nutrient deprivation. Cells of the nblR mutant (i) have more phycobilisomes than wild-type cells during nutrient-replete growth, (ii) do not degrade phycobilisomes during sulfur, nitrogen, or phosphorus limitation, (iii) cannot properly modulate the phycobilisome level during exposure to high light, and (iv) die rapidly when starved for either sulfur or nitrogen, or when exposed to high light. Apart from regulation of phycobilisome degradation, NblR modulates additional functions critical for cell survival during nutrient-limited and high-light conditions. NblR does not appear to be involved in acclimation responses that occur only during a specific nutrient limitation. In contrast, it controls at least some of the general acclimation responses; those that occur during any of a number of different stress conditions. NblR plays a pivotal role in integrating different environmental signals that link the metabolism of the cell to light harvesting capabilities and the activities of the photosynthetic apparatus; this modulation is critical for cell survival.

Mutations in toxR and toxS that separate transcriptional activation from DNA binding at the cholera toxin gene promoter

ToxR and ToxS are integral membrane proteins that activate the transcription of virulence genes in Vibrio cholerae. ToxR can be separated into three different domains: an N-terminal cytoplasmic DNA binding domain, a central transmembrane domain, and a C-terminal periplasmic domain. ToxS is thought to enhance ToxR-mediated transcriptional activation through a periplasmic interaction. By P22 challenge phage selection for DNA binding, in combination with a screen for cholera toxin gene transcription, 12 toxR and toxS positive control mutants producing variant ToxR proteins from the toxRS operon that bind to the cholera toxin promoter but that fail to activate transcription were isolated. One mutation in toxR specifies an E82K change in the predicted helix-loop-helix DNA binding domain and destroys ToxR-mediated activation. Seven toxR mutations included frameshifts and stop codons introduced into the periplasmic domain, and six of these mutations appeared to produce proteolytically processed shorter forms of ToxR, suggesting that even short periplasmic deletions alter the folding of ToxR in the periplasm. Deletion of toxS did not alter the steady-state level of ToxR, and ToxR was found to be capable of binding to DNA in the absence of ToxS even though it did not activate transcription. However, the ToxS L33S variant rendered ToxR susceptible to proteolysis, suggesting that the natural function of ToxS is to complex with ToxR. Therefore, certain alterations that map to the ToxR cytoplasmic DNA binding domain, to the periplasmic domain, or to ToxS separate DNA binding activity from activator function. These data support a model where proper assembly or stability of the periplasmic domain of ToxR is enhanced by ToxS. This chaperone-like activity of ToxS may be required for the formation of the transcriptional activation complex but not the ToxR-DNA complex.

Analysis of ToxR-dependent transcription activation of ompU, the gene encoding a major envelope protein in Vibrio cholerae

The membrane proteins ToxR and ToxS regulate a variety of genes associated with the virulence of Vibrio cholerae, the agent of human cholera. One of the ToxRS-regulated genes is the ompU gene, which encodes a porin that may also act as an adhesin. To begin to understand the mechanism of ompU transcription activation by ToxRS, we performed genetic and biochemical studies on the ompU promoter. Deletions with a 5' end-point at or downstream of -128, relative to the start site for transcription, did not direct expression of a lacZ reporter gene in wild-type V. cholerae, although the -128 promoter fragment did direct ToxRS-dependent reporter gene activity under conditions of ToxR overexpression in E. coli. Consistent with the activation data is that membranes containing ToxR and ToxS caused a gel electrophoretic mobility shift when mixed at low concentrations with deletion fragments whose end-point is at -211, but not with -128 or -68 fragments. ToxRS membranes did shift the -128 fragment when added at higher concentrations. DNase I footprinting analysis of ompU promoter DNA complexed with ToxRS membranes demonstrated protection of three sites: an upstream site ranging from -238 to -139, and two downstream sites ranging from -116 to -58 and -53 to -24. Within the DNA protected from DNase I digestion by ToxRS membranes, there are no elements bearing similarity to those identified previously within the promoters of two other ToxR-dependent genes, ctxA and toxT. We suggest a model for transcription activation that involves sequential ToxR-binding events to distinct regions in the ompU promoter.

Signal transduction in bacteria: molecular mechanisms of stimulus-response coupling

In bacteria, adaptive responses to changing environmental conditions are mediated by signal transduction systems that involve modular protein domains. Despite great diversity in the integration of domains into different systems, studies of individual components have revealed molecular strategies that are widely applicable. Studies of receptors have advanced our understanding of how information is transmitted across membranes, the determination of three-dimensional structures of domains of histidine protein kinase domains and response regulator proteins has begun to reveal the molecular basis of signaling via two-component phosphoryltransfer pathways, and the description of 'eukaryotic-like' protein domains involved in bacterial signaling has emphasized the universality of intracellular signaling mechanisms.

Solution structure of the DNA-binding domain and model for the complex of multifunctional hexameric arginine repressor with DNA

The structure of the monomeric DNA-binding domain of the Escherichia coli arginine repressor, ArgR, determined by NMR spectroscopy, shows structural homology to the winged helix-turn-helix (wHTH) family, a motif found in a diverse class of proteins including both gene regulators and gene organizers from prokaryotes and eukaryotes. Biochemical data on DNA binding by intact ArgR are used as constraints to position the domain on its DNA target and to derive a model for the hexamer-DNA complex using the known structure of the L-arginine-binding domain. The structural independence of the wHTH fold may be important for multimeric DNA-binding proteins that contact extended DNA regions with imperfect match to consensus sequences, a feature of many wHTH-domain proteins.

Synchrotron radiation applications to macromolecular crystallography

Progress has been rapid in the development and application of four different types of macromolecular crystallographic experiment at synchrotron hard X-ray sources: multiwavelength anomalous diffraction; studies of crystals with very large unit cell dimensions; structure determination at atomic or near-atomic resolution; and time-resolved studies. The results illustrate the interplay between the advanced technical capabilities available at new beamlines and more challenging scientific issues.

Recombination of protein domains facilitated by co-translational folding in eukaryotes

The evolution of complex genomes requires that new combinations of pre-existing protein domains successfully fold into modular polypeptides. During eukaryotic translation model two-domain polypeptides fold efficiently by sequential and co-translational folding of their domains. In contrast, folding of the same proteins in Escherichia coli is posttranslational, and leads to intramolecular misfolding of concurrently folding domains. Sequential domain folding in eukaryotes may have been critical in the evolution of modular polypeptides, by increasing the probability that random gene-fusion events resulted in immediately foldable protein structures.

Structural relationships in the OmpR family of winged-helix transcription factors

OmpR, a protein that regulates expression of outer membrane porin proteins in enteric bacteria, belongs to a large family of transcription factors. These transcription factors bind DNA and interact productively with RNA polymerase to activate transcription. The two functions, DNA-binding and transcriptional activation, have been localized within the 100 amino acid DNA-binding domain that characterizes members of the OmpR family. Both DNA binding and transcriptional activation by OmpR related proteins have remained poorly understood for lack of structural information or lack of sequence homology with transcription factors of known three-dimensional structure. The recently determined crystal structures of the Escherichia coli OmpR DNA-binding domain (OmpRc) have defined a new subfamily of "winged-helix-turn-helix" DNA-binding proteins. Structural elements of OmpRc can be assigned functional roles by analogy to other winged-helix DNA-binding proteins. A structure based sequence analysis of the OmpR family of transcription factors indicates specific roles for all conserved amino acid residues. Mutagenesis studies performed on several members of this family, OmpR, PhoB, ToxR and VirG, can now be interpreted with respect to the structure.