Conformational changes of the upstream DNA mediated by H-NS and FIS regulate E. coli RrnB P1 promoter activity

Bacterial chromatin proteins, transcription, and DNA topology: Inseparable partners in the control of gene expression

DNA in bacterial chromosomes is organized into higher-order structures by DNA-binding proteins called nucleoid-associated proteins (NAPs) or bacterial chromatin proteins (BCPs). BCPs often bind to or near DNA loci transcribed by RNA polymerase (RNAP) and can either increase or decrease gene expression. To understand the mechanisms by which BCPs alter transcription, one must consider both steric effects and the topological forces that arise when DNA deviates from its fully relaxed double-helical structure. Transcribing RNAP creates DNA negative (-) supercoils upstream and positive (+) supercoils downstream whenever RNAP and DNA are unable to rotate freely. This (-) and (+) supercoiling generates topological forces that resist forward translocation of DNA through RNAP unless the supercoiling is constrained by BCPs or relieved by topoisomerases. BCPs also may enhance topological stress and overall can either inhibit or aid transcription. Here, we review current understanding of how RNAP, BCPs, and DNA topology interplay to control gene expression.

DNA sequence-directed cooperation between nucleoid-associated proteins

Nucleoid-associated proteins (NAPs) are a class of highly abundant DNA-binding proteins in bacteria and archaea. While both the composition and relative abundance of the NAPs change during the bacterial growth cycle, surprisingly little is known about their crosstalk in mutually binding and stabilizing higher-order nucleoprotein complexes in the bacterial chromosome. Here, we use atomic force microscopy and solid-state nanopores to investigate long-range nucleoprotein structures formed by the binding of two major NAPs, FIS and H-NS, to DNA molecules with distinct binding site arrangements. We find that spatial organization of the protein binding sites can govern the higher-order architecture of the nucleoprotein complexes. Based on sequence arrangement the complexes differed in their global shape and compaction as well as the extent of FIS and H-NS binding. Our observations highlight the important role the DNA sequence plays in driving structural differentiation within the bacterial chromosome.

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The location of protein binding sites along DNA is important for 3D organization

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FIS protein forms DNA loops while H-NS forms compact DNA plectonemes

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FIS DNA loops inhibit H-NS from spreading over the DNA

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FIS and H-NS competition creates regions of ‘open’ and ‘closed’ DNA

Bacterial pathogen gene regulation: a DNA-structure-centred view of a protein-dominated domain

The mechanisms used by bacterial pathogens to regulate the expression of their genes, especially their virulence genes, have been the subject of intense investigation for several decades. Whole genome sequencing projects, together with more targeted studies, have identified hundreds of DNA-binding proteins that contribute to the patterns of gene expression observed during infection as well as providing important insights into the nature of the gene products whose expression is being controlled by these proteins. Themes that have emerged include the importance of horizontal gene transfer to the evolution of pathogens, the need to impose regulatory discipline upon these imported genes and the important roles played by factors normally associated with the organization of genome architecture as regulatory principles in the control of virulence gene expression. Among these architectural elements is the structure of DNA itself, its variable nature at a topological rather than just at a base-sequence level and its ability to play an active (as well as a passive) part in the gene regulation process.

Spatial organization of DNA sequences directs the assembly of bacterial chromatin by a nucleoid-associated protein

Structural differentiation of bacterial chromatin depends on cooperative binding of abundant nucleoid-associated proteins at numerous genomic DNA sites and stabilization of distinct long-range nucleoprotein structures. Histone-like nucleoid-structuring protein (H-NS) is an abundant DNA-bridging, nucleoid-associated protein that binds to an AT-rich conserved DNA sequence motif and regulates both the shape and the genetic expression of the bacterial chromosome. Although there is ample evidence that the mode of H-NS binding depends on environmental conditions, the role of the spatial organization of H-NS-binding sequences in the assembly of long-range nucleoprotein structures remains unknown. In this study, by using high-resolution atomic force microscopy combined with biochemical assays, we explored the formation of H-NS nucleoprotein complexes on circular DNA molecules having different arrangements of identical sequences containing high-affinity H-NS-binding sites. We provide the first experimental evidence that variable sequence arrangements result in various three-dimensional nucleoprotein structures that differ in their shape and the capacity to constrain supercoils and compact the DNA. We believe that the DNA sequence-directed versatile assembly of periodic higher-order structures reveals a general organizational principle that can be exploited for knowledge-based design of long-range nucleoprotein complexes and purposeful manipulation of the bacterial chromatin architecture.

Differential Regulation of the Surface-Exposed and Secreted SslE Lipoprotein in Extraintestinal Pathogenic Escherichia coli

Extra-intestinal pathogenic Escherichia coli (ExPEC) are responsible for diverse infections including meningitis, sepsis and urinary tract infections. The alarming rise in anti-microbial resistance amongst ExPEC complicates treatment and has highlighted the need for alternative preventive measures. SslE is a lipoprotein secreted by a dedicated type II secretion system in E. coli that was first identified as a potential vaccine candidate using reverse genetics. Although the function and protective efficacy of SslE has been studied, the molecular mechanisms that regulate SslE expression remain to be fully elucidated. Here, we show that while the expression of SslE can be detected in E. coli culture supernatants, different strains express and secrete different amounts of SslE when grown under the same conditions. While the histone-like transcriptional regulator H-NS strongly represses sslE at ambient temperatures, the variation in SslE expression at human physiological temperature suggested a more complex mode of regulation. Using a genetic screen to identify novel regulators of sslE in the high SslE-expressing strain UTI89, we defined a new role for the nucleoid-associated regulator Fis and the ribosome-binding GTPase TypA as positive regulators of sslE transcription. We also showed that Fis-mediated enhancement of sslE transcription is dependent on a putative Fis-binding sequence located upstream of the -35 sequence in the core promoter element, and provide evidence to suggest that Fis may work in complex with H-NS to control SslE expression. Overall, this study has defined a new mechanism for sslE regulation and increases our understanding of this broadly conserved E. coli vaccine antigen.

An Interplay among FIS, H-NS, and Guanosine Tetraphosphate Modulates Transcription of the Escherichia coli cspA Gene under Physiological Growth Conditions

CspA, the most characterized member of the csp gene family of Escherichia coli, is highly expressed not only in response to cold stress, but also during the early phase of growth at 37°C. Here, we investigate at molecular level the antagonistic role played by the nucleoid proteins FIS and H-NS in the regulation of cspA expression under non-stress conditions. By means of both probing experiments and immunological detection, we demonstrate in vitro the existence of binding sites for these proteins on the cspA regulatory region, in which FIS and H-NS bind simultaneously to form composite DNA-protein complexes. While the in vitro promoter activity of cspA is stimulated by FIS and repressed by H-NS, a compensatory effect is observed when both proteins are added in the transcription assay. Consistently with these findings, inactivation of fis and hns genes reversely affect the in vivo amount of cspA mRNA. In addition, by means of strains expressing a high level of the alarmone guanosine tetraphosphate ((p)ppGpp) and in vitro transcription assays, we show that the cspA promoter is sensitive to (p)ppGpp inhibition. The (p)ppGpp-mediated expression of fis and hns genes is also analyzed, thus clarifying some aspects of the regulatory loop governing cspA transcription.

Topological Behavior of Plasmid DNA

The discovery of the B-form structure of DNA by Watson and Crick led to an explosion of research on nucleic acids in the fields of biochemistry, biophysics, and genetics. Powerful techniques were developed to reveal a myriad of different structural conformations that change B-DNA as it is transcribed, replicated, and recombined and as sister chromosomes are moved into new daughter cell compartments during cell division. This article links the original discoveries of superhelical structure and molecular topology to non-B form DNA structure and contemporary biochemical and biophysical techniques. The emphasis is on the power of plasmids for studying DNA structure and function. The conditions that trigger the formation of alternative DNA structures such as left-handed Z-DNA, inter- and intra-molecular triplexes, triple-stranded DNA, and linked catenanes and hemicatenanes are explained. The DNA dynamics and topological issues are detailed for stalled replication forks and for torsional and structural changes on DNA in front of and behind a transcription complex and a replisome. The complex and interconnected roles of topoisomerases and abundant small nucleoid association proteins are explained. And methods are described for comparing in vivo and in vitro reactions to probe and understand the temporal pathways of DNA and chromosome chemistry that occur inside living cells.

A flexible integrative approach based on random forest improves prediction of transcription factor binding sites

Transcription factor binding sites (TFBSs) are DNA sequences of 6–15 base pairs. Interaction of these TFBSs with transcription factors (TFs) is largely responsible for most spatiotemporal gene expression patterns. Here, we evaluate to what extent sequence-based prediction of TFBSs can be improved by taking into account the positional dependencies of nucleotides (NPDs) and the nucleotide sequence-dependent structure of DNA. We make use of the random forest algorithm to flexibly exploit both types of information. Results in this study show that both the structural method and the NPD method can be valuable for the prediction of TFBSs. Moreover, their predictive values seem to be complementary, even to the widely used position weight matrix (PWM) method. This led us to combine all three methods. Results obtained for five eukaryotic TFs with different DNA-binding domains show that our method improves classification accuracy for all five eukaryotic TFs compared with other approaches. Additionally, we contrast the results of seven smaller prokaryotic sets with high-quality data and show that with the use of high-quality data we can significantly improve prediction performance. Models developed in this study can be of great use for gaining insight into the mechanisms of TF binding.

Differential stringent control of Escherichia coli rRNA promoters: effects of ppGpp, DksA and the initiating nucleotides

Transcription of rRNAs in Escherichia coli is directed from seven redundant rRNA operons, which are mainly regulated by their P1 promoters. Here we demonstrate by in vivo measurements that the amounts of individual rRNAs transcribed from the different operons under normal growth vary noticeably although the structures of all the P1 promoters are very similar. Moreover, we show that starvation for amino acids does not affect the seven P1 promoters in the same way. Notably, reduction of transcription from rrnD P1 was significantly lower compared to the other P1 promoters. The presence of DksA was shown to be crucial for the ppGpp-dependent downregulation of all P1 promoters. Because rrnD P1 is the only rrn promoter starting with GTP instead of ATP, we performed studies with a mutant rrnD promoter, where the initiating G+1 is replaced by A+1. These analyses demonstrated that the ppGpp sensitivity of rrn P1 promoters depends on the nature and concentration of initiating nucleoside triphosphates (iNTPs). Our results support the notion that the seven rRNA operons are differentially regulated and underline the importance of a concerted activity between ppGpp, DksA and an adequate concentration of the respective iNTP.

Genome-wide analysis of the H-NS and Sfh regulatory networks in Salmonella Typhimurium identifies a plasmid-encoded transcription silencing mechanism

The conjugative IncHI1 plasmid pSfR27 from Shigella flexneri 2a strain 2457T encodes the Sfh protein, a paralogue of the global transcriptional repressor H-NS. Sfh allows pSfR27 to be transmitted to new bacterial hosts with minimal impact on host fitness, providing a 'stealth' function whose molecular mechanism has yet to be determined. The impact of the Sfh protein on the Salmonella enterica serovar Typhimurium transcriptome was assessed and binding sites for Sfh in the Salmonella Typhimurium genome were identified by chromatin immunoprecipitation. Sfh did not bind uniquely to any sites. Instead, it bound to a subset of the larger H-NS regulatory network. Analysis of Sfh binding in the absence of H-NS revealed a greatly expanded population of Sfh binding sites that included the majority of H-NS target genes. Furthermore, the presence of plasmid pSfR27 caused a decrease in H-NS interactions with the S. Typhimurium chromosome, suggesting that the A + T-rich DNA of this large plasmid acts to titrate H-NS, removing it from chromosomal locations. It is proposed that Sfh acts as a molecular backup for H-NS and that it provides its 'stealth' function by replacing H-NS on the chromosome, thus minimizing disturbances to the H-NS-DNA binding pattern in cells that acquire pSfR27.

Investigation of the self-association and hetero-association interactions of H-NS and StpA from Enterobacteria

The nucleoid-associated protein H-NS and its paralogue StpA are global regulators of gene expression and form an integral part of the protein scaffold responsible for DNA condensation in Escherichia coli and Salmonella typhimurium. Although protein oligomerization is a requirement for this function, it is not entirely understood how this is accomplished. We address this by reporting on the self-association of H-NS and its hetero-association with StpA. We identify residues 1-77 of H-NS as being necessary and sufficient for high-order association. A multi-technique-based approach was used to measure the effects of salt concentration on the size distribution of H-NS and the thermal stability of H-NS and StpA dimers. The thermal stability of the StpA homodimer is significantly greater than that of H-NS(1-74). Investigation of the hetero-association of H-NS and StpA proteins suggested that the association of H-NS with StpA is more stable than the self-association of either H-NS or StpA with themselves. This provides a clear understanding of the method of oligomerization of these important proteins in effecting DNA condensation and reveals that the different associative properties of H-NS and StpA allow them to perform distinct, yet complementary roles in the bacterial nucleoid.

Nucleoid-associated proteins and bacterial physiology

Bacterial physiology is enjoying a renaissance in the postgenomic era as investigators struggle to interpret the wealth of new data that has emerged and continues to emerge from genome sequencing projects and from analyses of bacterial gene regulation patterns using whole-genome methods at the transcriptional and posttranscriptional levels. Information from model organisms such as the Gram-negative bacterium Escherichia coli is proving to be invaluable in providing points of reference for such studies. An important feature of this work concerns the nature of global mechanisms of gene regulation where a relatively small number of regulatory proteins affect the expression of scores of genes simultaneously. The nucleoid-associated proteins, especially Factor for Inversion Stimulation (Fis), IHF, H-NS, HU, and Lrp, represent a prominent group of global regulators and studies of these proteins and their roles in bacterial physiology are providing new insights into how the bacterium governs gene expression in ways that maximize its competitive advantage.

Studies on the expression of 6S RNA from E. coli: involvement of regulators important for stress and growth adaptation

The small bacterial 6S RNA has been recognized as a transcriptional regulator, facilitating the transition from exponential to stationary growth phase by preferentially inhibiting Eσ70RNA polymerase holoenzyme transcription. Consistent with this function, the cellular concentration of 6S RNA increases with stationary phase. We have studied the underlying mechanisms responsible for the growth phase-dependent differences in 6S RNA concentration. To this aim, we have analyzed the effects of the typical bacterial growth phase and stress regulators FIS, H-NS, LRP and StpA on 6S RNA expression. Measurements of 6S RNA accumulation in strains deficient in each one of these proteins support their contribution as potential regulators. Specific binding of the four proteins to DNA fragments containing 6S RNA promoters was demonstrated by gel retardation and DNase I footprinting. Moreover,in vitrotranscription analysis with both RNA polymerase holoenzymes, Eσ70and Eσ38, demonstrated a direct inhibition of 6S RNA transcription by H-NS, StpA and LRP, while FIS seems to act as a dual regulator.In vitrotranscription in the presence of ppGpp indicates that 6S RNA promoters are not stringently regulated. Our results underline that regulation of 6S RNA transcription depends on a complex network, involving a set of bacterial regulators with general importance in the adaptation to changing growth conditions.

SlyA and H-NS regulate transcription of the Escherichia coli K5 capsule gene cluster, and expression of slyA in Escherichia coli is temperature-dependent, positively autoregulated, and independent of H-NS

In this paper, we present the first evidence of a role for the transcriptional regulator SlyA in the regulation of transcription of the Escherichia coli K5 capsule gene cluster and demonstrate, using a combination of reporter gene fusions, DNase I footprinting, and electrophoretic mobility shift assays, the dependence of transcription on the functional interplay between H-NS and SlyA. Both SlyA and H-NS bind to multiple overlapping sites within the promoter in vitro, but their binding is not mutually exclusive, resulting in a remodeled nucleoprotein complex. In addition, we show that expression of the E. coli slyA gene is temperature-regulated, positively autoregulated, and independent of H-NS.

The role of LRP and H-NS in transcription regulation: involvement of synergism, allostery and macromolecular crowding

LRP has recently been shown to interact with the regulatory regions of bacterial ribosomal RNA promoters. Here we study details of the LRP-rDNA interaction by gel retardation and high-resolution footprinting techniques. We show that a second regulator for rRNA transcription, H-NS, facilitates the formation of a higher-order LRP-nucleoprotein complex, probably acting transiently as a DNA chaperone. The macromolecular crowding substance ectoine stabilizes the formation of this dynamic complex, while the amino acid leucine, as a metabolic effector, has the opposite effect. DNase I and hydroxyl radical footprint experiments with LRP-DNA complexes reveal a periodic change of the target DNA structure, which implies extensive DNA wrapping reaching into the promoter core region. We show furthermore that LRP binding is able to constrain supercoils, providing a link between DNA topology and regulation. The results support the conclusion that the bacterial DNA-binding protein LRP, assisted by H-NS, forms a repressive nucleoprotein structure involved in regulation of rRNA transcription. The formation of this regulatory structure appears to be directly affected by environmental changes.

Genome analysis of Escherichia coli promoter sequences evidences that DNA static curvature plays a more important role in gene transcription than has previously been anticipated

We have performed a computer analysis to study the prevalence of DNA static curvature in the regulatory regions of Escherichia coli, detecting a large number of operons with curved DNA fragments in their 5' upstream regions. A statistical analysis reveals that all the global transcription factors identified so far in E. coli have a tendency to regulate operons with curved DNA sequences in their upstream regions. In addition to these global regulators, we also found that the PurR, ArgR, FruR, TyrR, and CytR specific regulators present a similar propensity. Interestingly, for these cases we found no previous reference describing a possible relationship with curved DNA regions. To validate our theoretical results, we performed site-directed mutagenesis to reduce the degree of DNA curvature in the regulatory sequences of the aroG, pyrC, and argCBH operons. The effects of these changes were measured by polyacrylamide gel electrophoresis assays and further evaluated in vivo by transcriptional fusions to a reporter gene. All our results point toward a more widespread role of curved DNA in gene transcription, a fact that has previously been underestimated.

Characterization of hns genes from Erwinia amylovora

The small basic histone-like protein H-NS is known for bacteria to attenuate virulence of several animal pathogens. An hns homologue from E. amylovora was identified by complementing an E. coli hns-mutant strain with a cosmid library from E. amylovora. A 1.6 kb EcoRI-fragment complemented the mucoid phenotype and repressed the ss-glucosidase activity of E. coli PD32. The open reading frame encoding an H-NS-like protein of 134 amino acid was later shown to be located on plasmid pEA29 (McGhee and Jones 2000). A chromosomal hns gene was amplified with PCR consensus primers and localized near galU of E. amylovora. E. amylovora mutants were created by insertion of a resistance cassette, and the intact gene was inserted into a high copy number plasmid for constitutive expression. Purified chromosomal H-NS protein preferentially bound to a DNA fragment from the lsc region and bending was predicted for an adjacent fragment with the rlsB-promoter. Levan production was significantly increased by hns mutations. Synthesis of the capsular exopolysaccharide amylovoran and of levan were reduced, when hns from the E. amylovora plasmid was overexpressed. A mutation in chromosomal hns of E. amylovora increased amylovoran synthesis, and both mutations retarded symptom formation on immature pears.

The seven E. coli ribosomal RNA operon upstream regulatory regions differ in structure and transcription factor binding efficiencies

Ribosomal RNAs in E. coli are transcribed from seven operons, which are highly conserved in their organization and sequence. However, the upstream regulatory DNA regions differ considerably, suggesting differences in regulation. We have therefore analyzed the conformation of all seven DNA elements located upstream of the major E. coli rRNA P1 promoters. As judged by temperature-dependent gel electrophoresis with isolated DNA fragments comprising the individual P1 promoters and the complete upstream regulatory regions, all seven rRNA upstream sequences are intrinsically curved. The degree of intrinsic curvature was highest for the rrnB and rrnD fragments and less pronounced for the rrnA and rrnE operons. Comparison of the experimentally determined differences in curvature with programs for the prediction of DNA conformation revealed a generally high degree of conformity. Moreover, the analysis showed that the center of curvature is located at about the same position in all fragments. The different upstream regions were analyzed for their capacity to bind the transcription factors FIS and H-NS, which are known as antagonists in the regulation of rRNA synthesis. Gel retardation experiments revealed that both proteins interact with the upstream promoter regions of all seven rDNA fragments, with the affinities of the different DNA fragments for FIS and H-NS and the structure of the resulting complexes deviating considerably. FIS binding was non-cooperative, and at comparable protein concentrations the occupancy of the different DNA fragments varied between two and four binding sites. In contrast, H-NS was shown to bind cooperatively and intermediate states of occupancy could not be resolved for each fragment. The different gel electrophoretic mobilities of the individual DNA/protein complexes indicate variable structures and topologies of the upstream activating sequence regulatory complexes. Our results are highly suggestive of differential regulation of the individual rRNA operons.

H-NS is a part of a thermally controlled mechanism for bacterial gene regulation

Temperature is a primary environmental stress to which micro-organisms must be able to adapt and respond rapidly. Whereas some bacteria are restricted to specific niches and have limited abilities to survive changes in their environment, others, such as members of the Enterobacteriaceae, can withstand wide fluctuations in temperature. In addition to regulating cellular physiology, pathogenic bacteria use temperature as a cue for activating virulence gene expression. This work confirms that the nucleoid-associated protein H-NS (histone-like nucleoid structuring protein) is an essential component in thermoregulation of Salmonella. On increasing the temperature from 25 to 37 degrees C, more than 200 genes from Salmonella enterica serovar Typhimurium showed H-NS-dependent up-regulation. The thermal activation of gene expression is extremely rapid and change in temperature affects the DNA-binding properties of H-NS. The reduction in gene repression brought about by the increase in temperature is concomitant with a conformational change in the protein, resulting in the decrease in size of high-order oligomers and the appearance of increasing concentrations of discrete dimers of H-NS. The present study addresses one of the key complex mechanisms by which H-NS regulates gene expression.

LRP and H-NS - cooperative partners for transcription regulation atEscherichia colirRNA promoters

The synthesis of ribosomal RNAs in bacteria is tightly coupled to changes in the environment. This rapid adaptation is the result of several intertwined regulatory networks. The two proteins FIS and H-NS have previously been described to act as antagonistic transcription factors for rRNA synthesis. Here we provide evidence for another player, the regulatory protein LRP, which binds with high specificity to all seven Escherichia coli rRNA P1 promoter upstream regions (UAS). Comparison of the binding properties of LRP and H-NS, and characterization of the stabilities of the various complexes formed with the rRNA UAS regions revealed different binding modes. Binding studies with LRP and H-NS in combination demonstrated that the two proteins interacted with obvious synergism. The efficiency of LRP binding to the rRNA regulatory region is modified by the presence of the effector amino acid leucine, as has been shown for several other operons regulated by this transcription factor. The effect of LRP on the binding of RNA polymerase to the rrnB P1 promoter and in vitro transcription experiments indicated that LRP acts as a transcriptional repressor, thus resembling the activity of H-NS described previously. The results show for the first time that LRP binds to the regulatory region of bacterial rRNA promoters, and very likely contributes in combination with H-NS to the control of rRNA synthesis. From the known properties of LRP a mechanism can be inferred that couples rRNA synthesis to changes in nutritional quality.

Hierarchical gene regulators adapt to its host milieus

The facultative intracellular pathogen Salmonella enterica serovar Typhimurium possesses an elaborate set of virulence genes that enables the bacterium successfully to move between and adapt to the environment, different host organisms and various micro-niches within a given host. Expression of virulence attributes is by no means constitutive. Rather, the regulation of virulence determinants is highly coordinated and integrated into normal bacterial physiological responses. By integrating discriminating virulence gene regulators with conserved housekeeping regulatory processes, the bacteria can sense alterations in the repertoire of environmental cues, and translate the sensing events into a pragmatic and coordinated expression of virulence genes. While the description of transmissible genetic elements that import global gene regulatory factors into a cell brings conceptual problems into the established regulatory network, the existence of mobile gene regulators may actually enable the bacteria to further modulate virulence expression.

Control of rRNA synthesis in Escherichia coli: a systems biology approach

The first part of this review contains an overview of the various contributions and models relating to the control of rRNA synthesis reported over the last 45 years. The second part describes a systems biology approach to identify the factors and effectors that control the interactions between RNA polymerase and rRNA (rrn) promoters of Escherichia coli bacteria during exponential growth in different media. This analysis is based on measurements of absolute rrn promoter activities as transcripts per minute per promoter in bacterial strains either deficient or proficient in the synthesis of the factor Fis and/or the effector ppGpp. These absolute promoter activities are evaluated in terms of rrn promoter strength (V(max)/K(m)) and free RNA polymerase concentrations. Three major conclusions emerge from this evaluation. First, the rrn promoters are not saturated with RNA polymerase. As a consequence, changes in the concentration of free RNA polymerase contribute to changes in rrn promoter activities. Second, rrn P2 promoter strength is not specifically regulated during exponential growth at different rates; its activity changes only when the concentration of free RNA polymerase changes. Third, the effector ppGpp reduces the strength of the rrn P1 promoter both directly and indirectly by reducing synthesis of the stimulating factor Fis. This control of rrn P1 promoter strength forms part of a larger feedback loop that adjusts the synthesis of ribosomes to the availability of amino acids via amino acid-dependent control of ppGpp accumulation.

Adaptive changes in bacteria: a consequence of nonlinear transitions in chromosome topology?

Adaptive changes in bacteria are generally considered to result from random mutations selected by the environment. This interpretation is challenged by the non-randomness of genomic changes observed following ageing or starvation in bacterial colonies. A theory of adaptive targeting of sequences for enzymes involved in DNA transactions is proposed here. It is assumed that the sudden leakage of cAMP consecutive to starvation induces a rapid drop in the ATP/ADP ratio that inactivates the homeostasis in control of the level of DNA supercoiling. This phase change enables the emergence of local modifications in chromosome topology in relation to the missing metabolites, a first stage in expression of an adaptive status in which DNA transactions are induced. The nonlinear perspective proposed here is homologous to that already suggested for adaptation of pluricellular organisms during their development. In both cases, phases of robustness in regulation networks for genetic expression are interspaced by critical periods of breakdown of the homeostatic regulations during which, through isolation of nodes from a whole network, specific changes with adaptive value may locally occur.

Interaction of Ler at the LEE5 (tir) operon of enteropathogenic Escherichia coli

The genome of enteropathogenic Escherichia coli (EPEC) encodes a global regulator, Ler (locus of enterocyte effacement [LEE]-encoded regulator), which activates expression of several polycistronic operons within the 35.6-kb LEE pathogenicity island, including the LEE2-LEE3 divergent operon pair containing overlapping -10 regions and the LEE5 (tir) operon. Ler is a predicted 15-kDa protein that exhibits amino acid similarity with the nucleoid protein H-NS. In order to study Ler-mediated activation of virulence operons in EPEC, we used a molecular approach to characterize the interactions of purified Ler protein with the upstream regulatory sequences of the LEE5 operon. We determined the cis-acting DNA sequences necessary for Ler binding at LEE5 by mobility shift and DNase I protection assays, demonstrating that Ler acts directly at LEE5 by binding sequences between positions -190 and -73 in relation to the transcriptional start site. Based on the molecular weight of Ler, the similarity to H-NS, and the extended region of protection observed in a DNase I footprint at LEE5, we hypothesized that multiple Ler proteins bind upstream of the LEE5 promoter to increase transcriptional activity from a distance. Using an hns deletion strain, we demonstrated that like the LEE2-LEE3 operon pair, H-NS represses LEE5 transcription. We describe a model in which Ler activates transcription at both divergent overlapping paired and single promoters by displacing H-NS, which results in the disruption of a repressing nucleoprotein complex.

HU: promoting or counteracting DNA compaction?

The role of HU in Escherichia coli as both a protein involved in DNA compaction and as a protein with regulatory function seems to be firmly established. However, a critical look at the available data reveals that this is not true for each of the proposed roles of this protein. The role of HU as a regulatory or accessory protein in a number of systems has been thoroughly investigated and in many cases has been largely elucidated. However, almost 30 years after its discovery, convincing evidence for the proposed role of HU in DNA compaction is still lacking. Here we present an extensive literature survey of the available data which, in combination with novel microscopic insights, suggests that the role of HU could be the opposite as well. The protein is likely to play an architectural role, but instead of being responsible for DNA compaction it could be involved in antagonising compaction by other proteins such as H-NS.

Kinetic properties of rrn promoters in Escherichia coli

How do bacteria adapt and optimize their growth in response to different environments? The answer to this question is intimately related to the control of ribosome bio-synthesis. During the last decades numerous proposals have been made to explain this control but none has been definitive. To readdress the problem, we have used measurements of rRNA synthesis rates and rrn gene dosages in E. coli to find the absolute transcription rates of the average rrn operon (transcripts per min per operon) at different growth rates. By combining these rates with lacZ expression data from rRNA promoter-lacZ fusions, the abolute activities of the isolated rrnB P1 and P2 promoters were determined as functions of the growth rate in the presence and absence of Fis and of the effector ppGpp. The promoter activity data were analyzed to obtain the relative concentrations of free RNA polymerase, [R(f)], and the ratio of the Michaelis-Menten parameters, V(max)/K(m) (promoter strength), that characterize the promoter-RNA polymerase interaction. The results indicate that changes in the basal concentration of ppGpp can account for all growth-medium dependent regulation of the rrn P1 promoter strength. The P1 promoter strength was maximal when Fis was present and the level of ppGpp was undetectable during growth in rich media or in ppGpp-deficient strains; this maximal strength was 3-fold reduced when Fis was removed and the level of ppGpp remained undetectable. At ppGpp levels above 55 pmol per cell mass unit (OD(460)) during growth in poor media, the P1 promoter strength was minimal and not affected by the presence or absence of fis. The half-maximal value occurred at 20 pmol ppGpp/OD(460) and corresponds to an intracellular concentration of about 50 microM. In connection with previously published data, the results suggest that ppGpp reduces the P1 promoter strength directly, by binding RNA polymerase, and indirectly, by inhibiting the synthesis of Fis.

The bacterial regulatory protein H-NS--a versatile modulator of nucleic acid structures

The small DNA binding protein H-NS is attracting broad interest for its profound involvement in the regulation of bacterial physiology. It is involved in the regulation of many genes in response to a changing environment and functions in the adaptation to many different kinds of stress. Many H-NS-controlled genes, including the hns gene itself, are further linked to global regulatory networks. H-NS thus plays a key role in maintaining bacterial homeostasis under conditions of a rapidly changing environment. In this review we summarize recent results from combined biochemical and biophysical efforts which have yielded new insights into the three-dimensional structure and function of H-NS. The protein consists of two distinct domains separated by an unstructured linker region, and the structural details available today have helped to understand how these domains may interact with each other or with ligand molecules. Functional studies have, in addition, revealed mechanistic clues for the various H-NS activities, like temperature- or growth phase-dependent regulation. Important elements for the specific regulatory activities of H-NS comprise different modes of DNA binding, protein oligomerization, the competition with other regulators and the fact that the topology of the target DNA is modulated during complex formation. The distinctive ability to recognize nucleic acid structures in combination with other proteins also explains H-NS-dependent post-transcriptional activities where the interaction with defined RNA structures and the interference with RNA/protein complexes during mRNA translation are crucial for regulation. Thus, protein/protein interactions, in combination with the recognition and modulation of nucleic acid structures, are key elements of the different mechanisms which make H-NS such a versatile regulator.

Structural basis for H-NS-mediated trapping of RNA polymerase in the open initiation complex at the rrnB P1

The Escherichia coli H-NS protein is a nucleoid-associated protein involved in both transcription regulation and DNA compaction. Each of these processes involves H-NS-mediated bridge formation between adjacent DNA helices. With respect to transcription regulation, preferential binding sites in the promoter regions of different genes have been reported, and generally these regions are curved. Often H-NS binding sites overlap with promoter core regions or with binding sites of other regulatory factors. Not in all cases, however, transcriptional repression is the result of preferential binding by H-NS to promoter regions leading to occlusion of the RNA polymerase. In the case of the rrnB P1, H-NS actually stimulates open complex formation by forming a ternary RNAP.H-NS.DNA complex, while simultaneously stabilizing it to such an extent that promoter clearance cannot occur. To define the mechanism by which H-NS interferes at this step in the initiation pathway, the architecture of the RNAP.H-NS.DNA complex was analyzed by scanning force microscopy (SFM). The SFM images show that the DNA flanking the RNA polymerase in open initiation complexes is bridged by H-NS. On the basis of these data, we present a model for the specific repression of transcription initiation at the rrnB P1 by H-NS.

Regulation of gene expression in Vibrio cholerae by ToxT involves both antirepression and RNA polymerase stimulation

Co-ordinate expression of many virulence genes in the human pathogen Vibrio cholerae is under the direct control of the ToxT protein, including genes whose products are required for the biogenesis of the toxin-co-regulated pilus (TCP) and cholera toxin (CTX). This work examined interactions between ToxT and the promoters of ctx and tcpA genes. We found that a minimum of three direct repeats of the sequence TTTTGAT is required for ToxT-dependent activation of the ctx promoter, and that the region from -85 to -41 of the tcpA promoter contains elements that are responsive to ToxT-dependent activation. The role of H-NS in transcription of ctx and tcpA was also analysed. The level of activation of ctx-lacZ in an E. coli hns- strain was greatly increased even in the absence of ToxT, and was further enhanced in the presence of ToxT. In contrast, H-NS plays a lesser role in the regulation of the tcpA promoter. Electrophoretic mobility shift assays demonstrated that 6x His-tagged ToxT directly, and specifically, interacts with both the ctx and tcpA promoters. DNase I footprinting analysis suggests that there may be two ToxT binding sites with different affinity in the ctx promoter and that ToxT binds to -84 to -41 of the tcpA promoter. In vitro transcription experiments demonstrated that ToxT alone is able to activate transcription from both promoters. We hypothesize that under conditions appropriate for ToxT-dependent gene expression, ToxT binds to AT-rich promoters that may have a specific secondary conformation, displaces H-NS and stimulates RNA polymerase resulting in transcription activation.

An architectural role of the Escherichia coli chromatin protein FIS in organising DNA

The Escherichia coli chromatin protein FIS modulates the topology of DNA in a growth phase-dependent manner. In this study we have investigated the global effect of FIS binding on DNA architecture in vitro. We show that in supercoiled DNA molecules FIS binds at multiple sites in a non-random fashion and increases DNA branching. This global DNA reshaping effect is independent of the helical phasing of FIS binding sites. We propose, in addition to the previously inferred stabilisation of tightly bent DNA microloops in the upstream regions of certain promoters, that FIS may perform the distinct architectural function of organising branched plectonemes in the E.coli nucleoid.

A molecular mechanism for the repression of transcription by the H-NS protein

The H-NS protein is a major component of the bacterial nucleoid and plays a crucial role in the global gene regulation of enteric bacteria. Although H-NS does not exhibit a high DNA sequence specificity, a number of H-NS-responsive promoters have been shown to contain regions of intrinsic DNA curvature located either upstream or downstream of the transcription start point. We have studied H-NS binding to DNA and in vitro transcriptional regulation by H-NS at several synthetic promoters with or without curved sequences inserted upstream of the Pribnow box. We show how such inserts determine the final organization of H-NS-containing nucleoprotein complexes and how this affects transcription. We refine a two-step mechanism for the constitution of H-NS assemblies that are efficient in regulation.

Mechanism for the switch of phi29 DNA early to late transcription by regulatory protein p4 and histone-like protein p6

Bacteriophage phi29 gene expression takes place from four major promoters, three of them (A2b, A2c and A3) clustered within 219 bp at a central region of the genome. Transcription regulation of these promoters involves both a highly specific DNA-binding protein (p4) and a low specificity DNA-binding protein (p6) functionally related to prokaryotic histone-like proteins. Protein p6 forms extended oligomeric arrays along the phage DNA. In contrast, protein p4 binds specifically upstream of late promoter A3 and early promoter A2c. We have analysed the concomitant binding of p6 and p4 and found that the proteins cooperate with each other in the binding to the central region of the genome, resulting in a ternary p4-p6-DNA complex that affects local DNA topology. Through this complex, protein p6 exerts a direct role in the repression of promoter A2c, impeding unwinding of the DNA strands needed for open complex formation. In contrast, protein p6 functions by reinforcing the positioning of protein p4 in the repression of promoter A2b and activation of promoter A3, thereby facilitating p4-mediated transcription regulation.

Dynamic flexibility in the Escherichia coli genome

Empirical rules based on tetranucleotide parameters were presented to predict the structural parameters twist (Omega), roll (rho), tilt (tau) and slide (D(y)). A statistical mechanical model was used to analyze the flexibility of the Escherichia coli genome. The replication terminus region displayed a low level of flexibility. A strong correlation can be seen between G+C content and flexibility. Average flexibilities in the coding regions were found to be significantly larger than those in non-coding regions. The flexible characteristics in the 5'-neighborhood of the coding regions and in three class sigma promoter sequences in the E. coli genome were also analyzed.

Involvement of FIS in the H-NS-mediated regulation of virF gene of Shigella and enteroinvasive Escherichia coli

The mechanism of pathogenicity in Shigella and enteroinvasive Escherichia coli (EIEC) requires the co-ordinated expression of several genes located on both the virulence plasmid and the chromosome. We found that cells lacking a functional FIS protein (factor for inversion stimulation) are partially impaired in expressing the virulence genes and that full expression is totally restored when Shigella wild-type fis gene is offered in trans. We also identified virF, among the virulence genes, as a target of FIS-mediated activation and showed that FIS binds to four specific sites in the promoter region of virF. Previous studies have demonstrated that the expression of VirF, the first positive activator of a multistep regulatory cascade, is subject to temperature-dependent regulation by H-NS, one of the main nucleoid-associated proteins. We now demonstrate that two of the four FIS sites overlap one of the two H-NS sites responsible for thermoregulation (H-NS site I). FIS was found to exercise a direct positive transcriptional control at permissive temperature (37 degrees C), when H-NS fails to repress virF, as well as an indirect effect by partially counteracting H-NS inhibition at the transition temperature (32 degrees C). Our data indicate that FIS may be relevant for the rapid increase in virF expression after penetration of bacteria into the host.

Toward the three-dimensional structure of the Escherichia coli DNA-binding protein H-NS: A CD and fluorescence study

The DNA-binding protein H-NS compacts DNA and acts as a specific transcription factor regulating the expression of various bacterial genes. The small abundant protein binds to curved DNA without apparent sequence specificity and the exact nature of its DNA interaction is still unknown. H-NS lacks any common DNA-binding or oligomerization motif and except for a C-terminal fragment of the protein no high resolution structural information is available today. Since the complete structure of H-NS is of considerable interest for understanding its versatile regulatory features, and in lack of high-resolution data for the complete molecule, we have combined circular dichroism (CD) and fluorescence measurements to collect secondary- and higher-order structural information on H-NS. Comparison of CD analyses of wild type H-NS and functional defective mutants allowed assigning secondary structure elements to the N-terminal oligomerization domain of the protein. Moreover, according to fluorescence energy-transfer data we calculate a 45 A distance between the DNA-binding and the oligomerization domain of H-NS.

Structural basis for preferential binding of H-NS to curved DNA

The Escherichia coli H-NS protein is a nucleoid-associated protein involved in transcription regulation and DNA compaction. H-NS exerts its role in DNA condensation by non-specific interactions with DNA. With respect to transcription regulation preferential binding sites in the promoter regions of different genes have been reported. In this paper we describe the analysis of H-NS-DNA complexes on a preferred H-NS binding site by atomic force microscopy. On the basis of these data we present a model for the specific recognition of DNA by H-NS as a function of DNA curvature.

Interplay between three global regulatory proteins mediates oxygen regulation of the Escherichia coli cytochrome d oxidase (cydAB) operon

The Escherichia coli cydAB operon, encoding the subunits of the high-affinity cytochrome d oxidase, is maximally transcribed in microaerobiosis as a result of the combined action of the oxygen-responsive regulators Fnr and ArcA. Here, we report that the histone-like protein H-NS is an aerobic repressor of cydAB expression. ArcA is shown to antagonize H-NS action to render cydAB expression insensitive to H-NS repression in anaerobiosis. The targets for H-NS-mediated aerobic repression are the four oxygen-regulated promoters, designated P1, P2, P3 and P4. H-NS control is the result of H-NS binding to an extended region within the cydAB promoter element, including sequences upstream from and overlapping the four regulated promoters. We propose a regulatory model in which oxygen control of cydAB transcription is mediated by three alternative protein-DNA complexes that are assembled sequentially on the promoter region as the cells are shifted from aerobic to microaerobic and to anaerobic conditions. According to this model, ArcA-P plays a central role in cydAB regulation by antagonizing H-NS repression of cydAB transcription when oxygen becomes limiting. This allows peak gene expression and subsequent repression by Fnr under fully anaerobic conditions.

Global adaptations resulting from high population densities in Escherichia coli cultures

The scope of population density effects was investigated in steady-state continuous cultures of Escherichia coli in the absence of complications caused by transient environmental conditions and growth rates. Four distinct bacterial properties reflecting major regulatory and physiological circuits were analyzed. The metabolome profile of bacteria growing at high density contained major differences from low-density cultures. The 10-fold-elevated level of trehalose at higher densities pointed to the increased role of the RpoS sigma factor, which controls trehalose synthesis genes as well as the general stress response. There was an eightfold difference in RpoS levels between bacteria grown at 10(8) and at 10(9) cells/ml. In contrast, the cellular content of the DNA binding protein H-NS, controlling many genes in concert with RpoS, was decreased by high density. Since H-NS and RpoS also influence porin gene expression, the influence of population density on the intricate regulation of outer membrane composition was also investigated. High culture densities were found to strongly repress ompF porin transcription, with a sharp threshold at a density of 4.4 x 10(8) cells/ml, while increasing the proportion of OmpC in the outer membrane. The density-dependent regulation of ompF was maintained in rpoS or hns mutants and so was independent of these regulators. The consistently dramatic changes indicate that actively growing, high-density cultures are at least as differentiated from low-density cultures as are exponential- from stationary-phase bacteria.

The bacterial DNA-binding protein H-NS represses ribosomal RNA transcription by trapping RNA polymerase in the initiation complex

The interaction of the bacterial regulatory protein H-NS with RNA polymerase and the ribosomal RNA P1 promoter was analyzed to better understand the mechanism of H-NS-dependent transcriptional repression. We could show that initial binding of RNA polymerase to the promoter was not inhibited by the simultaneous interaction of H-NS, although H-NS binding sites extend into the core promoter region. Binding of sigma(70)-saturated RNA polymerase and H-NS to the promoter DNA occurs cooperatively and results in a stable complex of slower gel electrophoretic mobility as compared to complexes formed with the single proteins. The presence of the upstream curved H-NS binding site contributes strongly to the cooperative RNA polymerase-promoter interaction. By KMnO(4) modification of single-stranded template nucleotides we could show that open complex formation at the rrnB P1 promoter was not inhibited by H-NS binding. An increased KMnO(4) reactivity of several positions within the open complex rather supports the view that open complex formation is stimulated in presence of H-NS. Moreover, subtle changes in the modification pattern indicate that the open complex formed in the presence of H-NS are structurally distinct from the H-NS-free complex. In vitro transcriptional analysis of the abortive and productive yields revealed that the formation of transcription products longer than three nucleotides is dramatically reduced in the presence of H-NS, while the amount of shorter abortive products remained unaffected. Together the results demonstrate that H-NS inhibits transcription at the rrnB P1 promoter not by interfering with initial RNA polymerase binding but by blocking chain elongation steps subsequent to the first (two) phosphodiester bond formations. The mechanism of H-NS dependent repression at rRNA promoters can thus be explained as a trap which inhibits substrate NTP incorporation beyond template position +3 into the initial transcribing complex.

Regulation of rRNA transcription is remarkably robust: FIS compensates for altered nucleoside triphosphate sensing by mutant RNA polymerases at Escherichia coli rrn P1 promoters

We recently identified Escherichia coli RNA polymerase (RNAP) mutants (RNAP beta' Delta215-220 and beta RH454) that form extremely unstable complexes with rRNA P1 (rrn P1) core promoters. The mutant RNAPs reduce transcription and alter growth rate-dependent regulation of rrn P1 core promoters, because the mutant RNAPs require higher concentrations of the initiating nucleoside triphosphate (NTP) for efficient transcription from these promoters than are present in vivo. Nevertheless, the mutants grow almost as well as wild-type cells, suggesting that rRNA synthesis is not greatly perturbed. We report here that the rrn transcription factor FIS activates the mutant RNAPs more strongly than wild-type RNAP, thereby compensating for the altered properties of the mutant RNAPs. FIS activates the mutant RNAPs, at least in part, by reducing the apparent K(ATP) for the initiating NTP. This and other results suggest that FIS affects a step in transcription initiation after closed-complex formation in addition to its stimulatory effect on initial RNAP binding. FIS and NTP levels increase with growth rate, suggesting that changing FIS concentrations, in conjunction with changing NTP concentrations, are responsible for growth rate-dependent regulation of rrn P1 transcription in the mutant strains. These results provide a dramatic demonstration of the interplay between regulatory mechanisms in rRNA transcription.