The C-terminal region of the Vibrio fischeri LuxR protein contains an inducer-independent lux gene activating domain

Intracellular Ca(2+) mobilization and kinase activity during acylated homoserine lactone-dependent quorum sensing in Serratia liquefaciens

Quorum sensing in Gram-negative bacteria involves acylated homoserine lactones (AHLs) and a transcription factor, activated by the AHLs. In this study, a possible involvement of intracellular Ca(2+) as second messenger and/or protein kinase activity during signal transduction is analyzed. When N-hexanoyl-l-homoserine lactone was added to a suspension of Fura-2-loaded Serratia liquefaciens, there was a decline in [Ca(2+)](i), measured as a decrease in the Fura-2 fluorescence ratio. As controls, the addition of the signal molecule N-3-oxohexanoyl-l-homoserine lactone, which is not produced by S. liquefaciens, did not induce changes in [Ca(2+)](i). Using a protein kinase activity assay on AHL-stimulated cells, an increase in kinase activity after N-butanoyl-l-homoserine lactone stimulation of S. liquefaciens cells was detected, whereas the kinase activity induced by N-3-oxohexanoyl-l-homoserine lactone was not statistically significant. The conclusion from this study is that changes in [Ca(2+)](i) are involved in quorum sensing signal transduction in the Gram-negative bacteria S. liquefaciens. We also conclude that kinase activity is induced in S. liquefaciens upon AHL stimulation. We suggest that the transient intracellular [Ca(2+)] changes and kinase activity, activated by the AHL signal, are critical for the quorum-sensing signal transduction.

Amino acid residues in LuxR critical for its mechanism of transcriptional activation during quorum sensing in Vibrio fischeri

PCR-based site-directed mutagenesis has been used to generate 38 alanine-substitution mutations in the C-terminal 41 amino acid residues of LuxR. This region plays a critical role in the mechanism of LuxR-dependent transcriptional activation of the Vibrio fischeri lux operon during quorum sensing. The ability of the variant forms of LuxR to activate transcription of the lux operon was examined by using in vivo assays in recombinant Escherichia coli. Eight recombinant strains produced luciferase at levels less than 50% of that of a strain expressing wild-type LuxR. Western immunoblotting analysis verified that the altered forms of LuxR were expressed at levels equivalent to those of the wild type. An in vivo DNA binding-repression assay in recombinant E. coli was subsequently used to measure the ability of the variant forms of LuxR to bind to the lux box, the binding site of LuxR at the lux operon promoter. All eight LuxR variants found to affect cellular luciferase levels were unable to bind to the lux box. An additional 11 constructs that had no effect on cellular luciferase levels were also found to exhibit a defect in DNA binding. None of the alanine substitutions in LuxR affected activation of transcription of the lux operon without also affecting DNA binding. These results support the conclusion that the C-terminal 41 amino acids of LuxR are important for DNA recognition and binding of the lux box rather than positive control of the process of transcription initiation.

Quorum-sensing signal binding results in dimerization of TraR and its release from membranes into the cytoplasm

Promoter binding by TraR and LuxR, the activators of two bacterial quorum-sensing systems, requires their cognate acyl-homoserine lactone (acyl-HSL) signals, but the role the signal plays in activating these transcription factors is not known. Soluble active TraR, when purified from cells grown with the acyl-HSL, contained bound signal and was solely in dimer form. However, genetic and cross-linking studies showed that TraR is almost exclusively in monomer form in cells grown without signal. Adding signal resulted in dimerization of the protein in a concentration-dependent manner. In the absence of signal, monomer TraR localized to the inner membrane while growth with the acyl-HSL resulted in the appearance of dimer TraR in the cytoplasmic compartment. Affinity chromatography indicated that the N-terminus of TraR from cells grown without signal is hidden. Analysis of heterodimers formed between TraR and its deletion mutants localized the dimerization domain to a region between residues 49 and 156. We conclude that binding signal drives dimerization of TraR and its release from membranes into the cytoplasm.

Quorum sensing in the plant pathogen Erwinia carotovora subsp. carotovora: the role of expR(Ecc)

The production of the main virulence determinants of the plant pathogen Erwinia carotovora subsp. carotovora, the extracellular cell wall-degrading enzymes, is partly controlled by the diffusible signal molecule N-(3-oxohexanoyl)-L-homoserine lactone (OHHL). OHHL is synthesized by the product of the expI/carI gene. Linked to expI we found a gene encoding a putative transcriptional regulator of the LuxR-family. This gene, expR(Ecc), is transcribed convergently to the expI gene and the two open reading frames are partially overlapping. The ExpR(Ecc) protein showed extensive amino acid sequence similarity to the repressor EsaR from Pantoea stewartii subsp. stewartii (formerly Erwinia stewartii subsp. stewartii) and to the ExpR(Ech) protein of Erwinia chrysanthemi. Inactivation of the E. carotovora subsp. carotovora expR(Ecc) gene caused no decrease in virulence or production of virulence determinants in vitro. In contrast, there was a slight increase in the maceration capacity of the mutant strain. The effects of ExpR(Ecc) were probably mediated by changes in OHHL levels. Inactivation of expR(Ecc) resulted in increased OHHL levels during early logarithmic growth. In addition, overexpression of expR(Ecc) caused a clear decrease in the production of virulence determinants and part of this effect was likely to be caused by OHHL binding to ExpR(Ecc). ExpR(Ecc) did not appear to exhibit transcriptional regulation of expI, but the effect on OHHL was apparently due to other mechanisms.

Conversion of the Vibrio fischeri transcriptional activator, LuxR, to a repressor

The Vibrio fischeri luminescence (lux) operon is regulated by a quorum-sensing system that involves the transcriptional activator (LuxR) and an acyl-homoserine lactone signal. Transcriptional activation requires the presence of a 20-base inverted repeat termed the lux box at a position centered 42.5 bases upstream of the transcriptional start of the lux operon. LuxR has proven difficult to study in vitro. A truncated form of LuxR has been purified, and together with sigma(70) RNA polymerase it can activate transcription of the lux operon. Both the truncated LuxR and RNA polymerase are required for binding to lux regulatory DNA in vitro. We have constructed an artificial lacZ promoter with the lux box positioned between and partially overlapping the consensus -35 and -10 hexamers of an RNA polymerase binding site. LuxR functioned as an acyl-homoserine lactone-dependent repressor at this promoter in recombinant Escherichia coli. Furthermore, multiple lux boxes on an independent replicon reduced the repressor activity of LuxR. Thus, it appears that LuxR can bind to lux boxes independently of RNA polymerase binding to the promoter region. A variety of LuxR mutant proteins were studied, and with one exception there was a correlation between function as a repressor of the artificial promoter and activation of a native lux operon. The exception was the truncated protein that had been purified and studied in vitro. This protein functioned as an activator but not as a repressor in E. coli. The data indicate that the mutual dependence of purified, truncated LuxR and RNA polymerase on each other for binding to the lux promoter is a feature specific to the truncated LuxR and that full-length LuxR by itself can bind to lux box-containing DNA.

N-acyl homoserinelactone-mediated gene regulation in gram-negative bacteria

The view of bacteria as unicellular organisms has strong roots in the tradition of culturing bacteria in liquid media. However, in nature microbial activity is mainly associated with surfaces where bacteria form highly structured and cooperative consortia which are commonly referred to as biofilms. The ability of bacteria to organize structurally and to distribute metabolic activities between the different members of the consortium demands a high degree of coordinated cell-cell interaction. Recent work has established that many bacteria employ sophisticated intercellular communication systems that rely on small signal molecules to control the expression of multiple target genes. In Gram-negative bacteria, the most intensively investigated signal molecules are N-acyl-L-homoserine lactones (AHLs), which are utilized by the bacteria to monitor their own population densities in a process known as 'quorum sensing'. These density-dependent regulatory systems rely on two proteins, an AHL synthase, usually a member of the LuxI family of proteins, and an AHL receptor protein belonging to the LuxR family of transcriptional regulators. At low population densities cells produce a basal level of AHL via the activity of an AHL synthase. As the cell density increases, AHL accumulates in the growth medium. On reaching a critical threshold concentration, the AHL molecule binds to its cognate receptor which in turn leads to the induction/repression of AHL-regulated genes. To date, AHL-dependent quorum sensing circuits have been identified in a wide range of gram-negative bacteria where they regulate various functions including bioluminescence, plasmid conjugal transfer, biofilm formation, motility, antibiotic biosynthesis, and the production of virulence factors in plant and animal pathogens. Moreover, AHL signal molecules appear to play important roles in the ecology of complex consortia as they allow bacterial populations to interact with each other as well as with their eukaryotic hosts.

Signal-dependent DNA binding and functional domains of the quorum-sensing activator TraR as identified by repressor activity

TraR, a member of the LuxR family of quorum-sensing transcription factors, is responsible for the population density-dependent regulation of Ti plasmid conjugal transfer. The protein requires as coinducer an acyl-homoserine lactone signal molecule called AAI (Agrobacterium autoinducer) that is produced by the bacteria themselves. TraR only activates its target genes, making it difficult to determine whether interaction with AAI is required for binding DNA or for initiating transcription. To assess this, we converted TraR into a repressor by placing a copy of the tra box, an 18-bp inverted repeat believed to be the recognition site for this protein, over the -10 region of a promoter driving expression of lacZ. Repression of this promoter by TraR depended on AAI or, at higher concentrations, VAI, the closely related signal of Vibrio fischeri. C-terminal deletions as short as 2 aa and N-terminal deletions as short as 4 aa in TraR abolished both repressor and activator functions. The C-terminal mutants were strongly dominant over TraR, suggesting that they can form heteromultimers with the wild-type activator. Mutants of TraR with substitutions at Asp-10 and Gly-123 failed to activate a positively controlled reporter but continued to repress the chimeric promoter in an AAI-dependent manner. We conclude that TraR recognizes the tra box as its binding site, that binding of TraR to this site depends on AAI, and that the N-terminal half of the protein contains one or more domains that are required for activation but not for multimerization, for interaction with the acyl-homoserine lactone, or for DNA binding.

Involvement of the RNA polymerase alpha-subunit C-terminal domain in LuxR-dependent activation of the Vibrio fischeri luminescence genes

LuxR is a sigma(70) RNA polymerase (RNAP)-dependent transcriptional activator that controls expression of the Vibrio fischeri lux operon in response to an acylhomoserine lactone-cell density signal. We have investigated whether the alpha-subunit C-terminal domain (alphaCTD) of RNAP is required for LuxR activity. A purified signal-independent, LuxR C-terminal domain-containing polypeptide (LuxRDeltaN) was used to study the activation of transcription from the luxI promoter in vitro. Initiation of lux operon transcription was observed in the presence of LuxRDeltaN and wild-type RNAP but not in the presence of LuxRDeltaN and RNAPs with truncated alphaCTDs. We also studied the in vivo role of the RNAP alphaCTD in activation of lux transcription in Escherichia coli. This enabled a comparison of results obtained with full-length LuxR to those obtained with LuxRDeltaN. These in vivo studies indicated that both LuxR and LuxRDeltaN require the RNAP alphaCTD for activity. The results of DNase I protection studies showed that LuxRDeltaN-RNAP complexes can bind and protect the luxI promoter, but with less efficacy when the alphaCTD is truncated in comparison to the wild type. Thus, both in vitro and in vivo experiments demonstrated that LuxR-dependent transcriptional activation of the lux operon involves the RNAP alphaCTD and suggest that alphaCTD-LuxR interactions may play a role in recruitment of RNAP to the luxI promoter.

Quorum sensing in Vibrio fischeri: elements of the luxl promoter

Although cell density-dependent regulation of the luminescence genes in Vibrio fischeri is a model for quorum sensing in Gram-negative bacteria, relatively little is known about the promoter of the luminescence operon. The luminescence operon is activated by the LuxR protein, which requires a diffusible acylhomoserine lactone signal. The lux box, a 20 bp inverted repeat, is located in the luxl promoter region and is required for LuxR-dependent induction of the luminescence genes. Using primer extension, we mapped the LuxR-dependent transcriptional start site of the lux operon to 19 bp upstream of the luxl start codon. This indicates that the lux box is centred at -42.5 bp from the start of transcription. To gain evidence about the location of the -10 sequence, we placed a consensus -35 hexamer at different locations relative to the luxl transcriptional start site and measured constitutive levels of luminescence in recombinant Escherichia coli. The strongest constitutive promoter contained a TATAGT hexamer 17 bp from the -35 consensus sequence and 6 bp from the transcriptional start site. We propose that this is the -10 hexamer. Also in recombinant E. coli, both half-sites of the lux box were required for LuxR-dependent gene activation and for activation by an autoinducer-independent, monomeric LuxR deletion protein. LuxR-dependent activation of luminescence was eliminated when the lux box was centred at -47.5, -52.5 and -62.5 with respect to the luxl transcriptional start site. Our evidence, taken together with other information, points to a model in which a LuxR dimer overlaps the -35 region of the luxl promoter and functions as an ambidextrous activator with each LuxR subunit interacting with a different region of RNA polymerase.

Characterization of Proteus mirabilis precocious swarming mutants: identification of rsbA, encoding a regulator of swarming behavior

Proteus mirabilis swarming behavior is characterized by the development of concentric rings of growth that are formed as cyclic events of swarmer cell differentiation, swarming migration, and cellular differentiation are repeated during colony translocation across a surface. This cycle produces the bull's-eye colony often associated with cultures of P. mirabilis. How the cells communicate with one another to coordinate these perfectly synchronized rings is presently unknown. We report here the identification of a genetic locus that, when mutated, results in a precocious swarming phenotype. These mutants are defective in the temporal control of swarming migration and start swarming ca. 60 min sooner than wild-type cells. Unlike the wild type, precocious swarming mutants are also constitutive swarmer cells and swarm on minimal agar medium. The defects were found to be localized to a 5.4-kb locus on the P. mirabilis genome encoding RsbA (regulator of swarming behavior) and the P. mirabilis homologs to RcsB and RcsC. RsbA is homologous to membrane sensor histidine kinases of the two-component family of regulatory proteins, suggesting that RsbA may function as a sensor of environmental conditions required to initiate swarming migration. Introduction of a rsbA mutation back into the wild type via allelic-exchange mutagenesis reconstructed the precocious swarming phenotype, which could be complemented in trans by a plasmid-borne copy of rsbA. Overexpression of RsbA in wild-type cells resulted in precocious swarming, suggesting that RsbA may have both positive and negative functions in regulating swarming migration. A possible model to describe the role of RsbA in swarming migration is discussed.

Mutations affecting the alpha subunit of Bordetella pertussis RNA polymerase suppress growth inhibition conferred by short C-terminal deletions of the response regulator BvgA

The effects of short deletions of the C terminus of the BvgA response regulator protein of the BvgAS two-component system were examined in Bordetella pertussis. When present as a single copy in the chromosome, deletions removing as few as two amino acids conferred a completely Bvg- phenotype. When provided in trans, on the broad-host-range plasmid pRK290, under the control of the native bvgAS promoter, deletions of two or three amino acids conferred a profound growth inhibition which was dependent on the integrity and activity of the wild-type chromosomal bvgAS locus. It is proposed that this phenotype was the result of an inappropriate interaction of the mutant BvgA protein with the RNA polymerase enzyme, specifically the alpha subunit. Mutant strains in which this growth inhibition was relieved were isolated and characterized. Although most of the suppressor mutations affected either the mutant plasmid copy or the wild-type chromosomal bvg locus, three mutations which affected the alpha subunit of B. pertussis RNA polymerase were also isolated. Two of these resulted in increased levels of the alpha subunit, and one caused a substitution of glycine for the aspartic acid residue at position 171, in the N-terminal domain. All three mutations also resulted in a differential phenotype in that expression of fha was essentially normal, but expression of ptx was greatly reduced.

Self perception in bacteria: quorum sensing with acylated homoserine lactones

A variety of Gram-negative bacteria produce membrane permeant, acylated homoserine lactone (HL) pheromones that act as cell density cues. Synthesis and response to these factors requires proteins homologous to the Luxl acylhomoserine lactone synthase and the LuxR transcription factor from Vibrio fischeri. Recent genetic and biochemical studies have begun to provide a mechanistic understanding of acyl HL dependent gene regulation. Examination of the role of acyl HLs in diverse bacteria positions LuxR-Luxl type systems within an increasingly broad regulatory context and suggests that, in some bacteria, they comprise a global regulatory circuit.

Aromatic ligand binding and intramolecular signalling of the phenol-responsive sigma54-dependent regulator DmpR

The Pseudomonas-derived sigma54-dependent regulator DmpR has an amino-terminal A-domain controlling the specificity of activation by aromatic effectors, a central C-domain mediating an ATPase activity essential for transcriptional activation and a carboxy-terminal D-domain involved in DNA binding. In the presence of aromatic effectors, the DmpR protein promotes transcription from the -24, -12 Po promoter controlling the expression of specialized (methyl)phenol catabolic enzymes. Previous analysis of DmpR has led to a model in which the A-domain acts as an interdomain repressor of DmpR's ATPase and transcriptional promoting property until specific aromatic effectors are bound. Here, the autonomous nature of the A-domain in exerting its biological functions has been dissected by expressing portions of DmpR as independent polypeptides. The A-domain of DmpR is shown to be both necessary and sufficient to bind phenol. Analysis of phenol binding suggests one binding site per monomer of DmpR, with a dissociation constant of 16 microM. The A-domain is also shown to have specific affinity for the C-domain and to repress the C-domain mediated ATPase activity in vitro autonomously. However, physical uncoupling of the A-domain from the remainder of the regulator results in a system that does not respond to aromatics by its normal derepression mechanism. The mechanistic implications of aromatic non-responsiveness of autonomously expressed A-domain, despite its demonstrated ability to bind phenol, are discussed.

A pheromone-independent CarR protein controls carbapenem antibiotic synthesis in the opportunistic human pathogen Serratia marcescens

Strain ATCC 39006 of Serratia marcescens makes the same carbapenem, (5R)-carbapen-2-em-3-carboxylic acid (Car), as the Erwinia carotovora strain GS101. Unlike E. carotovora, where the onset of production occurs in the late-exponential phase of growth in response to the accumulation of the small diffusible pheromone N-(3-oxohexanoyl)-L-homoserine lactone (OHHL), in S. marcescens carbapenem is produced throughout the growth phase and does not appear to involve any diffusible pheromone molecule. Two cosmids capable of restoring antibiotic production in E. carotovora group I carbapenem mutants were isolated from an S. marcescens gene library. These cosmids were shown to contain a homologue of the E. carotovora carR gene, encoding a CarR protein with homology to the LuxR family of transcriptional regulators. The S. marcescens carR was subcloned and shown to be capable of complementing in trans, in the absence of OHHL, an E. carotovora carR carI double mutant, releasing the heterologous E. carotovora host from pheromone dependence for carbapenem production. The apparent OHHL-independence of the S. marcescens CarR explains the constitutive nature of carbapenem production in this strain of S. marcescens.

Octopine-type Ti plasmids code for a mannopine-inducible dominant-negative allele of traR, the quorum-sensing activator that regulates Ti plasmid conjugal transfer

Conjugal transfer of Agrobacterium tumefaciens Ti plasmids is regulated by two hierarchical signalling systems. Transfer is dependent on a subset of opines produced by the plant tumours induced by the bacterium. Induction also requires an acyl-homoserine lactone signal, called AAI, that is produced by the bacteria themselves. AAI is the co-inducer for TraR, the transcriptional activator required for expression of the tra regulon. Octopine induces conjugation of the octopine-mannityl opine-type Ti plasmids by regulating the expression of traR via OccR, the octopine-dependent activator of the opine regulon. We have discovered a second traR-like gene, trlR, on the octopine-mannityl opine-type Ti plasmids pTi15955 and pTiR10. This gene is located in an operon coding for a mannopine transport system and is expressed as part of the mannityl opine regulon. Sequence analysis indicated that trlR is a frameshift allele of traR, and the resulting protein lacks the carboxy-terminal domain thought to constitute the DNA-binding region of TraR. Expression of trlR inhibited octopine-induced conjugation of pTi15955 and pTiR10 by suppressing the TraR-mediated transcription of the tra and trb operons. Although TrlR had no effect on the expression of traR, TraR activated the expression of trlR. Southern hybridizations indicated that several other Ti and opine-catabolic plasmids contain more than one copy of genes homologous to traR. We propose that trlR is a dominant negative allele of traR and that TrlR inhibits conjugation by forming inactive heteromultimers with TraR.

Homoserine lactone-mediated gene regulation in plant-associated bacteria

Many plant-associated bacteria produce and utilize diffusible N-acyl-homoserine lactones (AHLs) to regulate the expression of specific bacterial genes and operons. AHL-mediated regulation utilizes two genes that encode proteins similar to the LuxI/LuxR system originally studied in the marine symbiont Vibrio fischeri. The LuxI-type proteins are AHL synthases that assemble the diffusible AHL signal. The LuxR-type proteins are AHL-responsive transcriptional regulatory proteins. LuxR proteins control the transcription of specific bacterial genes in response to the levels of AHL signal. To date, AHL-mediated gene regulation has been identified in a broad range of gram-negative bacteria, most of which are host-associated. However, it seems unlikely that such a widely conserved regulatory mechanism would be limited only to host-microbe interactions. These signals probably play central roles in ecological interactions among organisms in microbial communities by affecting communication among bacterial populations as well as between bacterial populations and their eukaryotic hosts.

Activity of the quorum-sensing regulator TraR of Agrobacterium tumefaciens is inhibited by a truncated, dominant defective TraR-like protein

Horizontal transfer of Agrobacterium tumefaciens tumour-inducing plasmids requires opines, which are released from plant tumours as nutrients for the bacteria. The opine octopine causes synthesis of the quorum-sensing TraR protein, which activates several tra promoters in the presence of a pheromone called Agrobacterium autoinducer (AAI). A gene, traS, was previously found on the same Ti plasmid in an operon that directs the uptake of mannopine, another opine. TraS strongly resembles TraR but lacks a DNA-binding module. TraS did not activate a TraR-dependent promoter and blocked TraR function, probably by forming inactive heteromultimers. Expression of traS was induced by mannopine, although this induction was strongly inhibited by the favoured catabolites succinate, glutamine and tryptone. Mannopine inhibited conjugation in a TraS-dependent fashion, and artificial overexpression of TraS also inhibited conjugation. Favoured catabolites restored tra gene expression in wild-type strains but not in strains that overexpress TraS. Downstream of traS is a gene encoding a truncated, defective chemoreceptor whose expression abolished chemotaxis.

Quorum sensing in Vibrio fischeri: essential elements for activation of the luminescence genes

LuxR is required for cell density-dependent activation of the Vibrio fischeri luminescence (lux) genes. It has not been possible to study full-length LuxR in vitro, but a polypeptide containing the C-terminal transcriptional-activator domain of LuxR (LuxRdeltaN) has been purified, and its binding to lux regulatory DNA has been investigated. By itself, LuxRdeltaN interacts with a region of lux regulatory DNA that is upstream of the lux box, which is a 20-bp element that is required for LuxR activation of the luminescence operon. Individually, neither the purified LuxRdeltaN nor RNA polymerase binds to the lux box region, but together the two proteins bind in synergy to the lux box-luxI promoter region. We show that binding of LuxRdeltaN to the upstream region is not a prerequisite for its synergistic binding with RNA polymerase to the lux box and the luxI promoter region. We also show that LuxRdeltaN and RNA polymerase are both required and sufficient for transcriptional activation of the lux operon. This argues against the hypothesis that LuxR functions to alleviate repression of the lux operon by another cellular factor. Rather, our data support the view that LuxR functions as an accessory factor that enables RNA polymerase to bind to and initiate transcription from the promoter of the lux operon.

Census and consensus in bacterial ecosystems: the LuxR-LuxI family of quorum-sensing transcriptional regulators

The importance of accurate demographic information is reflected in the United States Constitution, Article 1, which provides for a decennial census of this country's human population. Bacteria also conduct a census of their population and do so more frequently, more efficiently, and as far we know, with little if any of the political contentiousness caused by human demographers. Many examples have been found of particular bacterial genes, operons, or regulons that are expressed preferentially at high cell densities. Many of these are regulated by proteins related to the LuxR and LuxI proteins of Vibrio fischeri, and by a diffusible pheromone called an autoinducer. LuxR and LuxI and their cognate autoinducer (3-oxohexanoyl homoserine lactone, designated VAI-1) provide an important model to describe the functions of this family of proteins. LuxR is a VAI-1 receptor and a VAI-1-dependent transcriptional activator, and LuxI directs the synthesis of VAI-1. VAI-1 diffuses across the bacterial envelope, and intracellular concentrations of it are therefore strongly increased by nearby VAI-1-producing bacteria. Similar systems regulate pathogenesis factors in Pseudomonas aeruginosa and Erwinia spp., as well as T1 plasmid conjugal transfer in Agrobacterium tumefaciens, and many other genes in numerous genera of gram-negative bacteria. Genetic analyses of these systems have revealed a high degree of functional conservation, while also uncovering features that are unique to each.

Genetic evidence for interdomain regulation of the phenol-responsive final sigma54-dependent activator DmpR

The final sigma54-dependent DmpR activator regulates transcription of the dmp operon that encodes the enzymes for catabolism of (methyl)phenols. DmpR is expressed constitutively, but its transcriptional promoting activity is controlled positively in direct response to the presence of aromatic pathway substrates (effectors). DmpR has a distinct domain structure with the amino-terminal A-domain controlling the specificity of activation of the regulator by aromatic effectors (signal reception), a central C-domain mediating an ATPase activity essential for transcriptional activation, and a carboxyl-terminal D-domain involved in DNA binding. Deletion of the A-domain has been shown previously to result in an effector-independent transcriptional activator with constitutive ATPase activity. These results, in conjunction with the location of mutations within the A- and C-domains which exhibit an effector-independent (semiconstitutive) property, have led to a working model in which the A-domain serves to mask the ATPase and transcriptional promoting activity of the C-domain in the absence of effectors. To investigate the mechanism by which the A-domain exerts its repressive effect, we developed a genetic system to select positively for intramolecular second site revertants of DmpR. The results demonstrate (i) that mutations within the A-domain can suppress the semiconstitutive activity of C-domain located mutations and vice versa; (ii) that the C-domain located mutations do not influence the intrinsic ATPase and transcriptional promoting property of the C-domain in the absence of the A-domain; and (iii) that semiconstitutive mutations of the A- and C-domain have an additive effect. Taken together these results support a model in which the A-domain represses the function(s) of the C-domain by direct interactions between residues of the two domains.

Quorum sensing in Vibrio fischeri: probing autoinducer-LuxR interactions with autoinducer analogs

The Vibrio fischeri luminescence genes are activated by the transcription factor LuxR in combination with a diffusible signal compound, N-(3-oxohexanoyl) homoserine lactone, termed the autoinducer. We have synthesized a set of autoinducer analogs. Many analogs with alterations in the acyl side chain showed evidence of binding to LuxR. Some appeared to bind with an affinity similar to that of the autoinducer, but none showed a higher affinity, and many did not bind as tightly as the autoinducer. For the most part, compounds with substitutions in the homoserine lactone ring did not show evidence of binding to LuxR. The exceptions were compounds with a homocysteine thiolactone ring in place of the homoserine lactone ring. Many but not all of the analogs showing evidence of LuxR binding had some ability to activate the luminescence genes. None were as active as the autoinducer. While most showed little ability to induce luminescence, a few analogs with rather conservative substitutions had appreciable activity. Under the conditions we employed, some of the analogs showing little or no ability to induce luminescence were inhibitors of the autoinducer.

Involvement of N-acyl-L-hormoserine lactone autoinducers in controlling the multicellular behaviour of Serratia liquefaciens

Several bacterial species possess the ability to differentiate into highly motile swarmer cells capable of rapid surface colonization. In Serratia liquefaciens, we demonstrate that initiation of swarmer-cell differentiation involves diffusible signal molecules that are released into the growth medium. Using high-performance liquid chromatography (HPLC), high resolution mass spectrometry and nuclear magnetic resonance (NMR) spectroscopy, we identified N-butanoyl-L-homoserine lactone (BHL) and N-hex anoyl-L-homoserine lactone (HHL) in cell-free Serratia culture supernatants. BHL and HHL are present in a ratio of approximately 10:1 and their structures were unequivocally confirmed by chemical synthesis. The swrl (swarmer initiation) gene, the predicted translation product of which exhibits substantial homology to the LuxI family of putative N-acyl homoserine lactone (AHL) synthases is responsible for directing synthesis of both BHL and HHL. In an swrl mutant, swarming motility is abolished but can be restored by the addition of an exogenous AHL. These results add swarming motility to the rapidly expanding list of phenotypes known to be controlled through quorum sensing.

The amino-terminal domain of the prokaryotic enhancer-binding protein XylR is a specific intramolecular repressor

The mechanism under which the signal-reception amino-terminal portion (A domain) of the prokaryotic enhancer-binding protein XylR controls the activity of the regulator has been investigated through complementation tests in vivo, in which the various protein segments were produced as independent polypeptides. Separate expression of the A domain repressed the otherwise constitutive activity of a truncated derivative of XylR deleted of its A domain (XylR delta A). Such inhibition was not released by m-xylene, the natural inducer of the system. Repression caused by the A domain was specific for XylR because it did not affect activation of the sigma 54 promoter PnifH by a derivative of its cognate regulator, NifA, deleted of its own A domain. The A domain was also unable to repress the activity of a NifA-XylR hybrid protein resulting from fusing two-thirds of the central domain of NifA to the carboxyl-terminal third of XylR, which includes its DNA-binding domain. The inhibitory effect caused by the A domain of XylR on XylR delta A seems, therefore, to result from specific interactions in trans between the two truncated proteins and not from mere hindering of an activating surface.

The bacterial 'enigma': cracking the code of cell-cell communication

In recent years it has become clear that the production of N-acyl homoserine lactones (N-AHLs) is widespread in Gram-negative bacteria. These molecules act as diffusible chemical communication signals (bacterial pheromones) which regulate diverse physiological processes including bioluminescence, antibiotic production, plasmid conjugal transfer and synthesis of exoenzyme virulence factors in plant and animal pathogens. The paradigm for N-AHL production is in the bioluminescence (lux) phenotype of Photobacterium fischeri (formerly classified as Vibrio fischeri) where the signalling molecule N-(3-oxohexanoyl)-L-homoserine lactone (OHHL) is synthesized by the action of the LuxI protein. OHHL is thought to bind to the LuxR protein, allowing it to act as a positive transcriptional activator in an autoinduction process that physiologically couples cell density (and growth phase) to the expression of the bioluminescence genes. Based on the growing information on LuxI and LuxR homologues in other N-AHL-producing bacterial species such as Erwinia carotovora, Pseudomonas aeruginosa, Yersinia enterocolitica, Agrobacterium tumefaciens and Rhizobium leguminosarum, it seems that analogues of the P. fischeri lux autoinducer sensing system are widely distributed in bacteria. The general physiological function of these simple chemical signalling systems appears to be the modulation of discrete and diverse metabolic processes in concert with cell density. In an evolutionary sense, the elaboration and action of these bacterial pheromones can be viewed as an example of multicellularity in prokaryotic populations.

Evidence that the N-terminal region of the Vibrio fischeri LuxR protein constitutes an autoinducer-binding domain

The Vibrio fischeri luminescence genes are regulated by the LuxR protein and an N-acyl homoserine lactone compound termed the autoinducer. The C-terminal one-third of LuxR contains a domain that can interact with the transcription complex and activate the luminescence genes. On the basis of limited evidence it has been suggested that the N-terminal two-thirds of LuxR constitutes a domain that serves to bind the autoinducer. We show that tritium-labeled autoinducer binds to Escherichia coli cells in which LuxR is overexpressed. We also show that tritium-labeled autoinducer binds to E. coli in which truncated LuxR proteins missing portions of the C-terminal domain are expressed but does not bind to E. coli cells in which truncated LuxR proteins missing portions of the N-terminal region are expressed. Our results provide evidence that the autoinducer binds to LuxR and that in E. coli the N-terminal two-thirds of LuxR can fold into a polypeptide capable of binding the autoinducer in the absence of the C-terminal domain.

Synergistic binding of the Vibrio fischeri LuxR transcriptional activator domain and RNA polymerase to the lux promoter region

LuxR, the Vibrio fischeri luminescence gene (lux) activator, is the best-studied member of a family of bacterial transcription factors required for cell density-dependent expression of specific genes involved in associations with eukaryotic hosts. Neither LuxR nor any other LuxR homolog has been shown to bind DNA directly. We have purified the LuxR C-terminal transcriptional activator domain from extracts of recombinant Escherichia coli in which this polypeptide was expressed. The purified polypeptide by itself binds to lux regulatory DNA upstream of the lux box, a 20-bp palindrome that is required for LuxR activity in vivo, but it does not bind to the lux box. However, the LuxR C-terminal domain together with RNA polymerase protects a region including the lux box and the lux operon promoter from DNase I cleavage. There is very little protection of the lux operon promoter region from DNase I digestion in the presence of RNA polymerase alone. Apparently, there is a synergistic binding of the LuxR C-terminal domain and RNA polymerase to the promoter region. The upstream binding region for the purified polypeptide encompasses a binding site for cAMP receptor protein (CRP). Under some conditions, CRP binding can block the binding of the LuxR C-terminal domain to the upstream binding region, and it can also block the synergistic binding of the LuxR C-terminal domain and RNA polymerase to the lux box and luminescence gene promoter region. This description of DNA binding by the LuxR C-terminal domain should lead to an understanding of the molecular interactions of the LuxR family of transcriptional activators with regulatory DNA.

Mutations in the bvgA gene of Bordetella pertussis that differentially affect regulation of virulence determinants

By using chemical mutagenesis and genetic mapping, a search was undertaken for previously undescribed genes which may be involved in different regulatory mechanisms governing different virulence factors of Bordetella pertussis. Previous studies have shown that the fha locus encoding filamentous hemagglutinin is regulated directly by the bvgAS two component system, while regulation of ptx encoding pertussis toxin is less direct or occurs by a different mechanism. With a strain containing gene fusions to each of these regulated loci, screening was done for mutations which were defective for ptx expression but maintained normal or nearly normal levels of fha expression. Two mutations which had such a phenotype and were also deficient in adenylate cyclase toxin/hemolysin expression were found and characterized more fully. Both were found to affect residues in the C-terminal portion of the BvgA response regulator protein, a domain which shares sequence similarity with a family of regulatory proteins including FixJ, UhpA, MalT, RcsA, RcsB, and LuxR. The residues affected are within a region which, by extension from studies on the LuxR protein, may be involved in transcriptional activation.

Intramolecular signal transduction within the FixJ transcriptional activator: in vitro evidence for the inhibitory effect of the phosphorylatable regulatory domain

FixJ is a phosphorylatable 'response regulator' controlling the transcription of the key nitrogen fixation genes nifA and fixK in Rhizobium meliloti. Sequence and genetic analyses indicated that FixJ comprises an N-terminal phosphorylatable regulatory domain, FixJN, and a C-terminal transcriptional activator domain, FixJC. We have now overexpressed and purified the FixJC protein and show that it is fully active in an in vitro transcription system with purified RNA polymerase. FixJC appeared to act synergistically with RNA polymerase at the nifA promoter. Furthermore FixJC was more active in vitro than the full-length dephosphorylated FixJ protein. Therefore activity of FixJC is inhibited by FixJN within the FixJ protein. This inhibition is relieved by phosphorylation of FixJN. Such a negative mode of intramolecular signal transduction may be generalizable to other response regulators.

The Vibrio fischeri luminescence gene activator LuxR is a membrane-associated protein

The Vibrio fischeri luminescence (lux) genes are activated at sufficiently high culture densities by the transcriptional activator LuxR in combination with a diffusible signal compound termed autoinducer. We have used antibodies directed against LuxR in immunoprecipitation experiments to study the subcellular location of this transcription factor. The LuxR polypeptide was detected in membranes and not in the soluble pool of cytoplasmic proteins from V. fischeri. LuxR was not released from the membranes by 0.6 M KCl or by the nonionic detergents Nonidet P-40, N-octyl-beta-D-glucopyranoside, and Triton X-100. LuxR and a number of other V. fischeri proteins were released from the membranes by EDTA. The autoinducer had no detectable influence on the subcellular location of LuxR. In spheroplasts, neither the abundance nor the molecular mass of the LuxR antigen was influenced by treatment with proteinase K. Together with other information, these results indicate that LuxR is an amphipathic protein that is associated with the cytoplasmic membrane of V. fischeri.

GroESL proteins facilitate binding of externally added inducer by LuxR protein-containing E. coli cells

htpR- (rpoH, sigma 32 minus) strain of E. coli harbouring the whole lux system of Vibrio fischeri is very dim. We have recently shown that GroESL proteins fully recover the expression of the lux system in this strain. This work has been undertaken to study our assumption that the GroESL proteins stabilize the LuxR protein, thus enhancing the formation of LuxR-Inducer complex. E. coli htpR- cells harbouring the luxR gene were unable to bind extracellularly added inducer, while late logarithmically growing htpR+ strain bound small quantities of the inducer. Reduction in the nutrient content of the growth medium resulted in a large increase in the capability of these cells to bind the inducer. htpR+ or htpR- E. coli strains harbouring both the luxR and the groESL genes bound large quantities of the inducer. The molecular and ecological significance of these results is discussed.

Integration of multiple developmental signals in Bacillus subtilis through the Spo0A transcription factor

Multiple physiological and environmental signals are needed to initiate endospore formation in Bacillus subtilis. One key event controlling sporulation is activation of the Spo0A transcription factor. Spo0A is a member of a large family of conserved regulatory proteins whose activity is controlled by phosphorylation. We have isolated deletion mutations that remove part of the conserved amino terminus of Spo0A and make the transcription factor constitutively active, indicating that the amino terminus normally functions to keep the protein in an inactive state. Expression of an activated gene product is sufficient to activate expression of several sporulation genes in the absence of signals normally needed for initiation of sporulation. Our results indicate that nutritional, cell density, and cell-cycle signals are integrated through the phosphorylation pathway that controls activation of Spo0A.

Formation of the LuxR protein in the Vibrio fischeri lux system is controlled by HtpR through the GroESL proteins

The transcription of the luminescence (lux) system of Vibrio fischeri is regulated by the LuxR protein and an autoinducer. We previously showed that apart from these regulatory elements, the transcription of the lux system is negatively controlled by the LexA protein and positively controlled by the HtpR protein (sigma 32). This study was conducted in order to elucidate the mode of action of the HtpR protein. Using luxR-lacZ fused genes, we showed that the HtpR protein is essential for the maximum expression of beta-galactosidase activity in Escherichia coli lac mutant cells. Using this construct, we also demonstrated that luxR is preferentially expressed toward the end of the logarithmic phase of growth. Starvation and addition of ethanol significantly advanced the appearance of beta-galactosidase activity in htpR+ cells. The luminescence system of E. coli htpR+ cells harboring the pChv1 plasmid with a deletion in the luxI gene is induced in the presence of low and constant concentrations (150 pg/ml) of the inducer only at a late stage of the logarithmic phase of growth. When the cellular LuxR content is reduced, following 23 generations of exponential growth in Luria broth, a mid-log-phase culture does not respond to the inducer (150 pg/ml). On the basis of the above observations we suggest that the HtpR protein controls the formation of V. fischeri LuxR protein. Preliminary findings indicate that the HtpR protein acts through the chaperonins GroESL. E. coli htpR/pChv1 cells retained their full level of in vivo and in vitro luciferase activities in the presence of multiple copies of groESL genes. The possibility that GroESL proteins stabilize the native form of LuxR protein is discussed.

Evidence that GroEL, not sigma 32, is involved in transcriptional regulation of the Vibrio fischeri luminescence genes in Escherichia coli

In Escherichia coli, transcription of the inducible Vibrio fischeri luminescence operon, luxICDABE, has been reported to require sigma 32, the product of rpoH. Consistent with previous studies, we report that an E. coli delta rpoH mutant, KY1601 containing luxICDABE and luxR, which codes for the activator of luxICDABE transcription on a plasmid (pJE202), was weakly luminescent. Transformation of this E. coli strain with a plasmid containing rpoH under the control of the tac promoter resulted in high levels of cellular luminescence. However, the level of expression of the pJE202 luxICDABE was also high in E. coli 1603, a delta rpoH mutant with a second-site mutation that resulted in sigma 32-independent overexpression of the groE operon. Apparently, sigma 32 is not directly required for the transcription of luxICDABE in E. coli but is required for sufficient expression of groE, which is in turn required for the transcription of luxICDABE. This conclusion is supported by the finding that E. coli groE mutants containing pJE202 were weakly luminescent. In the E. coli delta rpoH mutant KY1601, the sigma 32 requirement for the transcription of luxICDABE was partially compensated for by the addition of saturating concentrations of the inducer to the culture medium and largely compensated for when cells were transformed with a luxR overexpression vector. These data support the hypothesis that sigma 32 is not required for transcription of luxICDABE. Rather, it appears that the products of groE are required for the folding of LuxR into an active protein, like they are for the folding of several other proteins.

Genetic dissection of DNA binding and luminescence gene activation by the Vibrio fischeri LuxR protein

The Vibrio fischeri luminescence (lux) genes are regulated by the 250-amino-acid-residue LuxR protein and a V. fischeri metabolite termed autoinducer. The V. fischeri lux regulon consists of two divergently transcribed units. Autoinducer and LuxR activate transcription of the luxICDABE operon and autoregulate the luxR transcriptional unit. LuxR proteins with C-terminal truncations of up to 40 amino acid residues coded by plasmids with luxR 3'-deletion mutations are functional in negative autoregulation as demonstrated by using a luxR::lacZ transcriptional fusion as a luxR promoter probe in Escherichia coli. The truncated LuxR proteins showed little or no ability to activate transcription of luxICDABE, as indicated by using luminescence as a sensitive indicator of promoter strength in E. coli. Besides having no detectable activity as positive regulators of luxICDABE, LuxR proteins with C-terminal truncations of more than 40 amino acid residues had reduced or no detectable activity as negative autoregulators. The results suggest that amino acid residues in LuxR prior to no. 211 are sufficient for lux DNA binding. Residues in the region of 211 to 250 constitute a C-terminal tail that appears to be involved in activation of luxICDABE transcription either by interacting physically with the transcription initiation complex or by affecting lux DNA in the vicinity of the promoter.

Cell density-dependent modulation of the Vibrio fischeri luminescence system in the absence of autoinducer and LuxR protein

Expression of the Vibrio fischeri luminescence genes (luxR and luxICDABEG) in Escherichia coli requires autoinducer (N-3-oxohexanoyl homoserine lactone) and LuxR protein, which activate transcription of luxICDABEG (genes for autoinducer synthase and the luminescence enzymes), and cyclic AMP (cAMP) and cAMP receptor protein (CRP), which activate transcription of the divergently expressed luxR gene. In E. coli and in V. fischeri, the autoinducer-LuxR protein-dependent induction of luxICDABEG transcription (called autoinduction) is delayed by glucose, whereas it is promoted by iron restriction, but the mechanisms for these effects are not clear. To examine in V. fischeri control of lux gene expression by autoinducer, cAMP, glucose, and iron, lux::Mu dI(lacZ) and lux deletion mutants of V. fischeri were constructed by conjugation and gene replacement procedures. beta-Galactosidase synthesis in a luxC::lacZ mutant exhibited autoinduction. In a luxR::lacZ mutant, complementation by the luxR gene was necessary for luminescence, and addition of cAMP increased beta-galactosidase activity four- to sixfold. Furthermore, a luxI::lacZ mutant produced no detectable autoinducer but responded to its addition with induced synthesis of beta-galactosidase. These results confirm in V. fischeri key features of lux gene regulation derived from studies with E. coli. However, beta-galactosidase specific activity in the luxI::lacZ mutant, without added autoinducer, exhibited an eight- to tenfold decrease and rise back during growth, as did beta-galactosidase and luciferase specific activities in the luxR::lacZ mutant and luciferase specific activity in a delta(luxR luxICD) mutant. The presence of glucose delayed the rise back in beta-galactosidase and luciferase specific activities in these strains, whereas iron restriction promoted it. Thus, in addition to transcriptional control by autoinducer and LuxR protein, the V. fischeri lux system exhibits a cell density-dependent modulation of expression that does not require autoinducer, LuxR protein, or known lux regulatory sites. The response of autoinducer-LuxR protein-independent modulation to glucose and iron may account for how these environmental factors control lux gene expressions.