Estimation of the effect of coumermycin A1 on Salmonella typhimurium promoters by using random operon fusions

S, Forquet R, Baude J, Villard C, Grand L, Popowycz F, Soulère L, Hommais F, Nasser W, Reverchon S, Meyer S. What is a supercoiling-sensitive gene? Insights from topoisomerase I inhibition in the Gram-negative bacterium Dickeya dadantii

DNA supercoiling is an essential mechanism of bacterial chromosome compaction, whose level is mainly regulated by topoisomerase I and DNA gyrase. Inhibiting either of these enzymes with antibiotics leads to global supercoiling modifications and subsequent changes in global gene expression. In previous studies, genes responding to DNA relaxation induced by DNA gyrase inhibition were categorised as 'supercoiling-sensitive'. Here, we studied the opposite variation of DNA supercoiling in the phytopathogen Dickeya dadantii using the non-marketed antibiotic seconeolitsine. We showed that the drug is active against topoisomerase I from this species, and analysed the first transcriptomic response of a Gram-negative bacterium to topoisomerase I inhibition. We find that the responding genes essentially differ from those observed after DNA relaxation, and further depend on the growth phase. We characterised these genes at the functional level, and also detected distinct patterns in terms of expression level, spatial and orientational organisation along the chromosome. Altogether, these results highlight that the supercoiling-sensitivity is a complex feature, which depends on the action of specific topoisomerases, on the physiological conditions, and on their genomic context. Based on previous in vitro expression data of several promoters, we propose a qualitative model of SC-dependent regulation that accounts for many of the contrasting transcriptomic features observed after DNA gyrase or topoisomerase I inhibition.

Quantitative contribution of the spacer length in the supercoiling-sensitivity of bacterial promoters

DNA supercoiling acts as a global transcriptional regulator in bacteria, but the promoter sequence or structural determinants controlling its effect remain unclear. It was previously proposed to modulate the torsional angle between the -10 and -35 hexamers, and thereby regulate the formation of the closed-complex depending on the length of the 'spacer' between them. Here, we develop a thermodynamic model of this notion based on DNA elasticity, providing quantitative and parameter-free predictions of the relative activation of promoters containing a short versus long spacer when the DNA supercoiling level is varied. The model is tested through an analysis of in vitro and in vivo expression assays of mutant promoters with variable spacer lengths, confirming its accuracy for spacers ranging from 15 to 19 nucleotides, except those of 16 nucleotides where other regulatory mechanisms likely overcome the effect of this specific step. An analysis at the whole-genome scale in Escherichia coli then demonstrates a significant effect of the spacer length on the genomic expression after transient or inheritable superhelical variations, validating the model's predictions. Altogether, this study shows an example of mechanical constraints associated to promoter binding by RNA Polymerase underpinning a basal and global regulatory mechanism.

Role of the Discriminator Sequence in the Supercoiling Sensitivity of Bacterial Promoters

DNA supercoiling acts as a global transcriptional regulator that contributes to the rapid transcriptional response of bacteria to many environmental changes. Although a large fraction of promoters from phylogenetically distant species respond to superhelical variations, the sequence or structural determinants of this behavior remain elusive. Here, we focus on the sequence of the "discriminator" element that was shown to modulate this response in several promoters. We develop a quantitative thermodynamic model of this regulatory effect, focusing on open complex formation during transcription initiation independently from promoter-specific regulatory proteins. We analyze previous and new expression data and show that the model predictions quantitatively match the in vitro and in vivo supercoiling response of selected promoters with mutated discriminator sequences. We then test the universality of this mechanism by a statistical analysis of promoter sequences from transcriptomes of phylogenetically distant bacteria under conditions of supercoiling variations (i) by gyrase inhibitors, (ii) by environmental stresses, or (iii) inherited in the longest-running evolution experiment. In all cases, we identify a robust and significant sequence signature in the discriminator region, suggesting that supercoiling-modulated promoter opening underpins a ubiquitous regulatory mechanism in the prokaryotic kingdom based on the fundamental mechanical properties of DNA and its basal interaction with RNA polymerase. IMPORTANCE In this study, we highlight the role of the discriminator as a global sensor of supercoiling variations and propose the first quantitative regulatory model of this principle, based on the specific step of promoter opening during transcription initiation. It defines the predictive rule by which DNA supercoiling quantitatively modulates the expression rate of bacterial promoters, depending on the G/C content of their discriminator and independently from promoter-specific regulatory proteins. This basal mechanism affects a wide range of species, which is tested by an extensive analysis of global high-throughput expression data. Altogether, ours results confirm and provide a quantitative framework for the long-proposed notion that the discriminator sequence is a significant determinant of promoter supercoiling sensitivity, underpinning the ubiquitous regulatory action of DNA supercoiling on the core transcriptional machinery, in particular in response to quick environmental changes.

Role of DNA Superhelicity in Regulation of Bacteroid-Associated Functions of Bradyrhizobium sp. Strain 32H1

Bradyrhizobium sp. strain 32H1 cells express a number of bacteroid-associated functions and repress some functions related to the free-living state when grown ex planta under conditions of low (0.2%) oxygen tension and relatively high levels (>8 mM) of medium K. Expression of the bacteroid-associated phenotype was blocked by the DNA gyrase inhibitor novobiocin. Because the degree of negative supercoiling of DNA is the result of the activities of both DNA gyrase and topoisomerase I, we measured these enzymes in cells grown under nitrogen-fixing (low O(2), high K) and non-nitrogen-fixing conditions (low O(2), low [50 muM] K or high O(2), high K). Lower topoisomerase I activities were seen in extracts from nitrogen-fixing cells than in those from non-nitrogen-fixing cells. In contrast, DNA gyrase levels were lower in high-O(2)-grown cells than under the other conditions tested. These differences are consistent with an increase in DNA superhelicity associated with growth under low-O(2), high-K conditions. A spontaneous mutant resistant to the DNA gyrase inhibitor ciprofloxacin was found to be constitutive with respect to the K requirement, because it expressed the bacteroid-associated phenotype when grown under low-O(2), low-K conditions. The mutant cells gave rise to effective nodules on Macroptilium atropurpureum and possessed the low topoisomerase I activities and high DNA gyrase levels of low-O(2)-, high-K-grown wild-type cells. Our data suggest that changes in DNA supercoiling resulting from low O(2) tension and a high K concentration exert a major influence on the expression of the bacteroid-associated phenotype.

An allele of gyrA prevents Salmonella enterica serovar Typhimurium from using succinate as a carbon source

A mutant gyrA allele resulting in an A271E substitution in the DNA gyrase protein generated a strain unable to grow on the C(4)-dicarboxylates succinate, malate, and fumarate. Bacteria harboring gyrA751 displayed decreased negative supercoiling in cells. Expression of the dctA gene, which encodes the C(4)-dicarboxylate transporter, was reduced in a gyrA751 mutant, providing the first evidence that dctA expression is supercoiling sensitive and uncovering a simple metabolic screen for lesions in gyrase that reduce negative supercoiling.

DNA supercoiling — a global transcriptional regulator for enterobacterial growth?

A fundamental principle of exponential bacterial growth is that no more ribosomes are produced than are necessary to support the balance between nutrient availability and protein synthesis. Although this conclusion was first expressed more than 40 years ago, a full understanding of the molecular mechanisms involved remains elusive and the issue is still controversial. There is currently agreement that, although many different systems are undoubtedly involved in fine-tuning this balance, an important control, and in our opinion perhaps the main control, is regulation of the rate of transcription initiation of the stable (ribosomal and transfer) RNA transcriptons. In this review, we argue that regulation of DNA supercoiling provides a coherent explanation for the main modes of transcriptional control - stringent control, growth-rate control and growth-phase control - during the normal growth of Escherichia coli.

Long-term experimental evolution in Escherichia coli. XII. DNA topology as a key target of selection

The genetic bases of adaptation are being investigated in 12 populations of Escherichia coli, founded from a common ancestor and serially propagated for 20,000 generations, during which time they achieved substantial fitness gains. Each day, populations alternated between active growth and nutrient exhaustion. DNA supercoiling in bacteria is influenced by nutritional state, and DNA topology helps coordinate the overall pattern of gene expression in response to environmental changes. We therefore examined whether the genetic controls over supercoiling might have changed during the evolution experiment. Parallel changes in topology occurred in most populations, with the level of DNA supercoiling increasing, usually in the first 2000 generations. Two mutations in the topA and fis genes that control supercoiling were discovered in a population that served as the focus for further investigation. Moving the mutations, alone and in combination, into the ancestral background had an additive effect on supercoiling, and together they reproduced the net change in DNA topology observed in this population. Moreover, both mutations were beneficial in competition experiments. Clonal interference involving other beneficial DNA topology mutations was also detected. These findings define a new class of fitness-enhancing mutations and indicate that the control of DNA supercoiling can be a key target of selection in evolving bacterial populations.

Effect of varying the supercoiling of DNA on transcription and its regulation

The effect of superhelicity of DNA templates on transcription is well documented in several cases. However, the amount of supercoiling that is needed to bring about any changes and the steps at which such effects are exerted were not systematically studied. We investigated the effect of DNA supercoiling on transcription from a set of promoters present on a plasmid by using a series of topoisomers with different superhelical densities ranging from totally relaxed to more than physiological. In vitro transcription assays with these topoisomers in the absence and presence of gene regulatory proteins showed that the effect of negative supercoiling on intrinsic transcription varies from promoter to promoter. Some of those promoters, in which DNA superhelicity stimulated transcription, displayed specific optima of superhelical density while others did not. The results also showed that the amounts of abortive RNA synthesis from two of the promoters decreased and full-length RNA increased with increasing supercoiling, indicating for the first time an inverse relationship between full-length and abortive RNA synthesis and supporting a role of DNA superhelicity in promoter clearance. DNA supercoiling might also influence the point of RNA chain termination. Furthermore, the effect of varying the amount of supercoiling on the action of gene regulatory proteins suggested the mode of action, which is consistent with previous results. Our results underscore the importance of DNA supercoiling in fine-tuning promoter activities, which should be relevant in cell physiology given that local changes in chromosomal supercoiling must occur in different environments.

Transcriptional regulation of the ospAB and ospC promoters from Borrelia burgdorferi

OspA, OspB and OspC are the major outer surface proteins of Borrelia burgdorferi that are differentially synthesized in response to environmental conditions, including culture temperature. We found that DNA was more negatively supercoiled in B. burgdorferi cultures grown at 23 degrees C compared with cultures grown at 35-37 degrees C. We examined the regulation of ospAB and ospC transcription by temperature and DNA supercoiling. DNA supercoiling was relaxed by adding coumermycin A1, an antibiotic that inhibits DNA gyrase. Syntheses of the major outer surface proteins, expression of the ospA and ospC genes and the activities of the ospAB operon and ospC gene promoters were assayed. ospA product levels decreased, whereas ospC product levels increased after shifting from 23 degrees C to 35 degrees C or after adding coumermycin A1. In addition, OspC synthesis was higher in a gyrB mutant than in wild-type B. burgdorferi. Promoter activity was quantified using cat reporter fusions. Increasing temperature or relaxing supercoiled DNA resulted in a decrease in ospAB promoter activity in B. burgdorferi, but not in Escherichia coli, as well as an increase in ospC promoter activity in both bacteria. ospC promoter activity was increased in an E. coli gyrB mutant with an attenuated DNA supercoiling phenotype. These results suggest that B. burgdorferi senses environmental changes in temperature by altering the level of DNA supercoiling, which then affects the expression of the ospAB operon and the ospC gene. This implies that DNA supercoiling acts as a signal transducer for environmental regulation of outer surface protein synthesis.

Gene expression changes triggered by exposure of Haemophilus influenzae to novobiocin or ciprofloxacin: combined transcription and translation analysis

The responses of Haemophilus influenzae to DNA gyrase inhibitors were analyzed at the transcriptional and the translational level. High-density microarrays based on the genomic sequence were used to monitor the expression levels of >80% of the genes in this bacterium. In parallel the proteins were analyzed by two-dimensional electrophoresis. DNA gyrase inhibitors of two different functional classes were used. Novobiocin, as a representative of one class, inhibits the ATPase activity of the enzyme, thereby indirectly changing the degree of DNA supercoiling. Ciprofloxacin, a representative of the second class, obstructs supercoiling by inhibiting the DNA cleavage-resealing reaction. Our results clearly show that different responses can be observed. Treatment with the ATPase inhibitor Novobiocin changed the expression rates of many genes, reflecting the fact that the initiation of transcription for many genes is sensitive to DNA supercoiling. Ciprofloxacin mainly stimulated the expression of DNA repair systems as a response to the DNA damage caused by the stable ternary complexes. In addition, changed expression levels were also observed for some genes coding for proteins either annotated as "unknown function" or "hypothetical" or for proteins not directly involved in DNA topology or repair.

Extensive regulation compromises the extent to which DNA gyrase controls DNA supercoiling and growth rate of Escherichia coli

As DNA gyrase is the only enzyme to supercoil DNA actively, we address here the question of whether it does play the expected dominant role in controlling the level of DNA supercoiling and growth rate in Escherichia coli. We modulated the expression of DNA gyrase around its wild-type level, and measured the effect on plasmid supercoiling and growth rate. As both the activity and the transcription rate of DNA gyrase are sensitive to DNA supercoiling we distinguish two types of control (with control defined as the percentage change observed on a 1% modulation of a parameter). The first type of control, here named inherent control, quantifies the effect of a sustained modulation of the transcription rate of gyrase. At its wild-type expression level this inherent control exerted by DNA gyrase on growth rate was very low, i.e. c mu/gyrase = 0.05 - 0.00, as was the inherent control on DNA supercoiling, c aLK/gyrase = 0.2. The second type of control, here named global control, quantifies the effect of a change in gyrase activity whilst allowing the cell to respond by readjusting gyrase transcription. Both types of control are linked via the sensitivity of gyrase transcription to DNA supercoiling, as determined from the inherent control by gyrase of the gyrase promoter activity using a chromosomal gyrB:lacZ fusion. As expected, the latter control was negative, but small, i.e. c gyr promoter/gyrase=-0.3. The global control by gyrase of active linking number was 0.1. These results show that although gyrase is an essential enzyme it does not have a high control, on either growth rate or DNA supercoiling. Homeostatic regulation of physiological DNA structure appears to dominate. At low degrees of DNA supercoiling, the control by DNA gyrase and by the other topoisomerases is much stronger.

Regulation of DNA gyrase operon in Mycobacterium smegmatis: a distinct mechanism of relaxation stimulated transcription

BACKGROUND

The topological state of DNA is a result of the diverse influences of various topoisomerases present in the cell. Amongst these, DNA gyrase is the only enzyme that is capable of supercoiling DNA. In all the eubacterial cells tested so far, DNA gyrase has proved to be essential for survival. We have earlier cloned gyr genes from Mycobacterium smegmatis. Unlike the situation in Escherichia coli, genes encoding the two subunits of gyrase are present as a contiguous stretch in the M. smegmatis genome.

RESULTS

We have demonstrated that the two subunits are encoded by a single dicistronic message, with the transcriptional start site mapping 57 base pairs upstream of the putative translational start of the gyrB ORF. The gyr promoter is specific to M. smegmatis and does not function in E. coli. We have shown that the synthesis of DNA gyrase in M. smegmatis is induced by novobiocin-a known inhibitor of gyrase. Short fragments encompassing the promoter region, when cloned in a promoter selection vector, do not show any response to changes in supercoil levels. Larger fragments show a supercoil sensitive behaviour, as seen in the genomic context.

CONCLUSIONS

The gene structure and the transcriptional organization of the gyr operon suggest an overall regulatory scheme that is unique to mycobacteria. In contrast to E. coli, promoter and regions in its vicinity are not sufficient to confer supercoil sensitivity. Promoter distal regions- 600 bp downstream of the promoter-appear to be necessary for relaxation-stimulated transcription in M. smegmatis.

How is osmotic regulation of transcription of the Escherichia coli proU operon achieved? A review and a model

The proU operon in enterobacteria encodes a binding-protein-dependent transporter for the active uptake of glycine betaine and L-proline, and serves an adaptive role during growth of cells in hyperosmolar environments. Transcription of proU is induced 400-fold under these conditions, but the underlying signal transduction mechanisms are incompletely understood. Increased DNA supercoiling and activation by potassium glutamate have each been proposed in alternative models as mediators of proU osmoresponsivity. We review here the available experimental data on proU regulation, and in particular the roles for DNA supercoiling, potassium glutamate, histone-like proteins of the bacterial nucleoid, and alternative sigma factors of RNA polymerase in such regulation. We also propose a new unifying model, in which the pronounced osmotic regulation of proU expression is achieved through the additive effects of at least three separate mechanisms, each comprised of a cis element [two promoters P1 and P2, and negative-regulatory-element (NRE) downstream of both promoters] and distinct trans-acting factors that interact with it: stationary-phase sigma factor RpoS with P1, nucleoid proteins HU and IHF with P2, and nucleoid protein H-NS with the NRE. In this model, potassium glutamate may activate proU expression through each of the three mechanisms whereas DNA supercoiling has a very limited role, if any, in the osmotic induction of proU transcription. We also suggest that proU may be a virulence gene in the pathogenic enterobacteria.

Regulation of gene expression at a distance: the hypothetical role of regulatory protein-mediated topological changes of DNA

A theoretical model is presented that a regulatory protein may activate the transcription of a promoter by interacting with a single remote operator. In response to an inducer molecule the regulatory protein bound to the operator undergoes a conformational change, and might mediate a B to Z-DNA conversion of the operator. This transition would remove both helical turns and supercoils from the intervening region between the operator and the promoter, resulting in the correct spatial arrangement of the -10 and -35 hexamers of the promoter, which therefore can be efficiently transcribed.

Supercoiling and map stability in the bacterial chromosome

A major goal of comparative genomics is an understanding of the forces which control gene order. This assumes that gene order is important, a supposition backed by the existence of genomic colinearity between many related species. In the bacterial chromosome, a polarity in the order of genes has been suggested, influenced by distance and orientation relative to the origin of DNA replication. We propose a model of the bacterial chromosome in which gene order is maintained by the adaptation of gene expression to local superhelical context. This force acts not directly at the genomic level but rather at the local gene level. A full understanding of gene-order conservation must therefore come from the bottom up.

Energy buffering of DNA structure fails when Escherichia coli runs out of substrate

To study how changes in the [ATP]/[ADP] ratio affect the level of DNA supercoiling in Escherichia coli, the cellular content of H(+)-ATPase was modulated around the wild-type level. A relatively large drop in the [ATP]/[ADP] ratio from the normal ratio resulted in a small increase in the linking number of our reporter plasmid (corresponding to a small decrease in negative supercoiling). However, when cells depleted their carbon and energy source, the ensuing drop in energy state was accompanied by a strong increase in linking number. This increase was not due to reduced transcription of the DNA in the absence of growth substrate, since rifampin had virtually no effect on the plasmid linking number. To examine whether DNA supercoiling depends more strongly on the cellular energy state at low [ATP]/[ADP] ratios than at high ratios, we used cells that were already at a low energy state after substrate depletion; after the addition of an uncoupler to these cells, the [ATP]/[ADP] ratio decreased further, which resulted in a strong increase in plasmid linking number. Our results suggest that the strong thermodynamic control of DNA supercoiling takes over at low [ATP]/[ADP] ratios, whereas at high ratios homeostatic control mechanisms attenuate thermodynamic control.

Chromosomal supercoiling in Escherichia coli

The Escherichia coli chromosome is compacted into 40-50 negatively supercoiled domains. It has been proposed that these domains differ in superhelical density. Here, we present evidence that this is probably not the case. A modified Tn10 transposable element was inserted at a number of locations around the E. coli chromosome. This element, mTn10-plac-lacZ+, contains the lac operon promoter, plac, whose activity increases with increasing superhelical density, fused to a lacZ+ reporter gene. Although mTn10-plac-lacZ+ fusion expression varies as much as approximately threefold at different insertion sites, the relative levels of expression from these elements are unaffected by replacing plac with the gyrA promoter, pgyrA, which has a reciprocal response to changes in superhelical density. Importantly, topoisomerase mutations and coumermycin, which inhibits DNA gyrase activity, alter mTn10-plac-lacZ+ and mTn10-pgyrA-lacZ+ fusion expression in expected ways, showing that the elements remain responsive to supercoiling and that topoisomerase activity is required for maintaining superhelical density. Fusion expression is not affected by anaerobic growth or osmotic shock, two physiological conditions thought to alter supercoiling. The approximately threefold difference in mTn10-plac-lacZ+ and mTn10-pgyrA-lacZ+ fusion expression observed at different sites may be explained by regional differences in chromosomal copy number that arise from bidirectional replication. Together, these results strongly suggest that the E. coli chromosomal domains do not differ in functional superhelical density.

Topoisomerase mutations affect the relative abundance of many Escherichia coli proteins

The relative abundance of 88 proteins was measured in extracts from three strains of Escherichia coli K-12 that are isogenic except for the topA and gyrB genes. Mutations in these genes slightly raise or lower, respectively, steady-state DNA supercoiling levels but have little effect on growth rate. Altered protein abundances were observed in the mutant strains relative to wild type. Many proteins exhibited minimum abundance at wild-type supercoiling levels, and other proteins exhibited maximal abundance at relaxed levels. A smaller number showed maximal abundance at elevated levels of supercoiling. These data suggest that small, non-lethal changes in DNA supercoiling can have widespread effects on patterns of gene expression.

A mutation in a new gene of Escherichia coli, psu, requires secondary mutations for survival: psu mutants express a pleiotropic suppressor phenotype

A mutation in an apparently new gene of Escherichia coli, psu, maps close to ara (1.3 min). psu mutants express a pleiotropic suppressor phenotype in which several auxotrophic requirements and some deletion mutations are suppressed. psu cloned in pBR322 can be maintained by the transformed cell only in the presence of several secondary mutations which accumulate in cultures of psu mutants and have an apparently compensatory role. The accumulation of secondary mutations is not due to mutator activity. The secondary mutations can each act as a suppressor of an auxotrophic requirement in the absence of psu, while suppression of deletions requires the presence of psu. Thus, the suppressor phenotype of psu mutants is due to both psu and the secondary mutations. The functions of psu and the secondary mutations are not known. However, two observations suggest an association with DNA gyrase and with DNA supercoiling. (i) psu mutants are highly resistant to oxolinic acid, the gyrase A inhibitor, while the secondary mutants vary from being very sensitive to more resistant than the wild-type strain. (ii) Novobiocin, which decreases the level of DNA supercoiling, significantly stimulates suppression of auxotrophy in some secondary mutants.

Transcriptional regulation of Mn-superoxide dismutase gene (sodA) of Escherichia coli is stimulated by DNA gyrase inhibitors

The expression of manganese-containing superoxide dismutase (sodA) in Escherichia coli using sodA::lacZ gene fusion was found to be stimulated by DNA gyrase inhibitors, nalidixic acid, or coumermycin A1. Aerobically, the gyrase inhibitors increased the expression of sodA::lacZ in the presence or absence of either paraquat or the iron chelator 2,2'-dipyridyl. The concentrations of the inhibitors used were found to reduce DNA supercoiling. Treatment of wild-type cells (sodA+) with nalidixic acid increased the transcription of MnSOD mRNA. Anaerobically, the expression of sodA::lacZ in wild-type cells was not affected by nalidixic acid. However, nalidixic acid had a stimulatory effect on the anaerobic expression of sodA::lacZ in cells preinduced by the iron chelator as well as in mutants derepressed in sodA expression by virtue of their lacking the trans-acting repressor proteins or the cis-acting regulatory elements needed for sodA regulation. The results indicate that the effect of DNA gyrase inhibitors is secondary to the cis- and trans-regulatory elements of sodA and suggest that changes in DNA topology may affect transcriptional regulation of sodA.

Interrelated effects of DNA supercoiling, ppGpp, and low salt on melting within the Escherichia coli ribosomal RNA rrnB P1 promoter

The formation of complexes containing high levels of DNA melting at the ribosomal RNA rrnB P1 promoter in vitro is shown to be facilitated by DNA supercoiling or low salt. The effector nucleotide ppGpp is ineffective under these conditions. The loss of supercoils or addition of salt increases the effectiveness of ppGpp in inhibiting formation of these complexes. In vivo plasmid DNA supercoiling is shown to decrease during starvation protocols that also increase levels of ppGpp. The results suggest that ppGpp regulation may be affected by the state of DNA supercoiling in vivo.

DNA twist as a transcriptional sensor for environmental changes

A variety of reports describe shifts in the environment which cause a corresponding change in the measured linking number of plasmid DNA isolated from bacterial cells. This change in linking number is often attributed to a change in superhelical density. This, coupled with the observation that transcription is often dependent upon the superhelical density of the DNA template seen in vitro, has led to the suggestion that superhelical density may control expression of certain genes. However, since many environmental changes could, in principle, influence DNA twist itself, then the measured differences in linking number, delta Lk, may simply be a consequence of variation in twist according to the relationship delta Lk = delta Tw + delta Wr, where delta Tw and delta Wr are changes in twist and writhe, respectively. In fact, we show that when an environmental change causes a change in the helical pitch of the DNA, and if the superhelical density of DNA is regulated to remain constant according to the homeostatic model of Menzel and Gellert, then delta Lk approximately delta Tw. We have found that there are a number of published reports describing variation in promoter activity as a function of linking number that can be explained by considering twist. We suggest that there are classes of sigma 70 promoters whose ability to be recognized by RNA polymerase is exquisitely sensitive to the relative orientation of the -35 and -10 regions, and environmental conditions can control this relative orientation by changing DNA twist.(ABSTRACT TRUNCATED AT 250 WORDS)

Bacterial DNA supercoiling and [ATP]/[ADP]. Changes associated with a transition to anaerobic growth

Shifting Escherichia coli from aerobic to anaerobic growth caused changes in the ratio of [ATP]/[ADP] and in negative supercoiling of chromosomal and plasmid DNA. Shortly after lowering oxygen tension, both [ATP]/[ADP] and supercoiling transiently decreased. Under conditions of exponential anaerobic growth, both were higher than under aerobic conditions. These correlations may reflect an effect of [ATP]/[ADP] on DNA gyrase, since in vitro [ATP]/[ADP] influences the level of plasmid supercoiling attained when gyrase is either introducing or removing supercoils. When the supercoiling activity of gyrase was perturbed by a mutation in gyrB, a shift to anaerobic conditions resulted in plasmid supercoil relaxation similar to that seen with wild-type. However, the low level of supercoiling in the mutant persisted during a time when supercoiling in wild-type recovered and then exceeded aerobic levels. Thus, changes in oxygen tension can alter DNA supercoiling through an effect on gyrase, and correlations exist between changes in supercoiling and changes in the intracellular ratio of [ATP]/[ADP].

Sequence analysis and expression of the Salmonella typhimurium asr operon encoding production of hydrogen sulfide from sulfite

A chromosomal locus of Salmonella typhimurium which complements S. typhimurium asr (anaerobic sulfite reduction) mutants and confers on Escherichia coli the ability to produce hydrogen sulfide from sulfite was recently cloned (C. J. Huang and E. L. Barrett, J. Bacteriol. 172:4100-4102, 1990). The DNA sequence and the transcription start site have been determined. Analysis of the sequence and gene products revealed a functional operon containing three genes which have been designated asrA, asrB, and asrC, encoding peptides of 40, 31, and 37 kDa, respectively. The predicted amino acid sequences of both asrA and asrC contained arrangements of cysteines characteristic of [4Fe-4S] ferredoxins. The sequence of asrB contained a typical nucleotide-binding region. The sequence of asrC contained, in addition to the ferredoxinlike cysteine clusters, two other cysteine clusters closely resembling the proposed siroheme-binding site in biosynthetic sulfite reductase. Expression of lacZ fused to the asr promoter was repressed by oxygen and induced by sulfite. Analysis of promoter deletions revealed a region specific for sulfite regulation and a second region required for anaerobic expression. Computer-assisted DNA sequence analysis revealed a site just upstream of the first open reading frame which had significant homology to the FNR protein-binding site of E. coli NADH-linked nitrite reductase. However, asr expression by the fusion plasmid was not affected by site-specific mutations within the apparent FNR-binding site.

Transcription regulates oxolinic acid-induced DNA gyrase cleavage at specific sites on the E. coli chromosome

Prominent DNA gyrase-mediated cleavage sites, induced by oxolinic acid, occur at specific, but infrequent, locations on the Escherichia coli chromosome. These sites, which we call toposites, may represent high affinity DNA gyrase binding sites or may mark chromosomal regions that accumulate superhelical stress. Toposites are usually grouped in 5 to 10 kb clusters that are mostly 50 to 100 kb apart. The total number of clusters on the chromosome is between 50 and 100. The location of sites depends on the local sequence. The extent of DNA gyrase cleavage at toposites can be strongly modulated by transcription occurring at as far as 35 kb away.

Identification of a heat shock promoter in the topA gene of Escherichia coli

The transcriptional activity of the topA gene which codes for topoisomerase I was examined. An in vitro assay determined that the P1 promoter was dependent on the sigma 32 subunit of RNA polymerase. The transcriptional activity of the four topA promoters was examined by nuclease S1 mapping of the transcripts during a heat shock. This sigma 32-dependent promoter was shown to function as a heat shock promoter, although topoisomerase I is not a heat shock protein. A possible method of compensation of transcription activity by the other promoters to maintain the level of topoisomerase I during heat shock is proposed.

Histone-like protein H1 (H-NS), DNA supercoiling, and gene expression in bacteria

Changes in DNA supercoiling in response to environmental signals such as osmolarity, temperature, or anaerobicity appear to play an underlying role in the regulation of gene expression in bacteria. Extensive genetic analyses have implicated the osmZ gene in this regulatory process: osmZ mutations are highly pleiotropic and alter the topology of cellular DNA. We have shown that the product of the osmZ gene is the "histone-like" protein H1 (H-NS). Protein H1 is one of the most abundant components of bacterial chromatin and binds to DNA in a relatively nonspecific fashion. These data imply a regulatory role for one of the major components of bacterial chromatin and provide support for the notion that changes in DNA topology and/or chromatin structure play a role in regulating gene expression.

Inhibition of DNA gyrase activity in an in vitro transcription-translation system stimulates gyrA expression in a DNA concentration dependent manner. Evidence for the involvement of factors which may be titrated

Stimulation of gyrA expression in an in vitro transcription-translation system by novobiocin, a DNA gyrase inhibitor, depends on the DNA concentration in the extract. At low DNA concentrations (less than 20 micrograms/ml) we note significant stimulation (2 to 25 x) upon the addition of novobiocin; at high DNA concentrations, stimulation is minimal. This observation is not due to the limited capacity of the system to transcribe or relax DNA. Using an extract prepared from a novobiocin-resistant strain of Escherichia coli, we were able to show that DNA gyrase mediates the novobiocin-enhanced expression. In an experiment with a fixed level of a gyrA-lac template, we found that the addition of a second non-Lac template increased expression from the gyrA-lac template, while concomitantly decreasing the extent of novobiocin stimulation. These observations are consistent with an inhibitory factor that can be titrated by increasing the DNA concentration and whose effects are minimized when the DNA template is in a relaxed conformation. The results of a mixed-extract experiment using two extracts that differ in their activities and degrees of novobiocin stimulation are also consistent with an inhibitory factor that mediates the relaxation-induced stimulation of transcription.

Expression of Salmonella typhimurium genes required for invasion is regulated by changes in DNA supercoiling

The ability to enter intestinal epithelial cells is an essential virulence factor of salmonellae. We have previously cloned a group of genes (invA, B, C, and D) that allow S. typhimurium to penetrate tissue culture cells (J. E. Galán and R. Curtiss III, Proc. Natl. Acad. Sci. USA 86:6383-6387, 1989). Transcriptional and translational cat and phoA fusions to invA (the proximal gene in the invABC operon) were constructed, and their expression was studied by measuring the levels of alkaline phosphatase or chloramphenicol acetyltransferase activity in mutants grown under different conditions. It was found that when strains containing the fusions were grown on media with high osmolarity, a condition known to increase DNA superhelicity, the level of invA transcription was approximately eightfold higher than that in strains grown on media with low osmolarity. The osmoinducibility of invA was independent of ompR, which controls the osmoinducibility of other genes. Strains grown in high-osmolarity media in the presence of subinhibitory concentrations of gyrase inhibitors (novobiocin or coumermycin A1), which reduce the level of DNA supercoiling, showed reduced expression of invA. Nevertheless, invA was poorly expressed in topA mutants of S. typhimurium, which have increased DNA superhelicity. In all cases, the differential expression of the invasion genes was correlated with the ability of S. typhimurium to penetrate tissue culture cells. These results taken together indicate that expression of S. typhimurium invasion genes is affected by changes in DNA supercoiling and suggest that this may represent a way in which this organism regulates the expression of these genes.

The unexpected antitermination of gyrA-directed transcripts is enhanced by DNA relaxation

We show that transcription originating at the gyrA promoter of Escherichia coli is less subject to termination at the lambda Toop terminator (22% read-through) than is transcription originating from either the galOP (1% read-through) or topA (3% read-through) control regions. Furthermore, termination of the gyrA transcripts decreases (60% read-through) upon relaxation of the template DNA. We believe that events related to stimulation of transcription at the gyrA promoter by DNA relaxation are responsible for the enhanced terminator read-through.

An overlap between osmotic and anaerobic stress responses: a potential role for DNA supercoiling in the coordinate regulation of gene expression

The regulation of several genes in response to osmotic and anaerobic stress has been examined. We have demonstrated a clear overlap between these two regulatory signals. Thus, the osmotically induced proU and ompC genes require anaerobic growth for optimum induction while the anaerobically induced tppB gene is also regulated by osmolarity. Furthermore, normal expression of tppB and ompC requires the positive regulatory protein OmpR, yet this requirement can be partially, or even fully, overcome by altering the growth conditions. Finally, the pleiotropic, anaerobic regulatory locus, oxrC, is also shown to affect expression of the osmotically regulated proU gene. The oxrC mutation is shown to affect the level of negative supercoiling of plasmid DNA and its effects on gene expression can be explained as secondary consequences of altered DNA topology. We suggest that there is a class of 'stress-regulated' genes that are regulated by a common mechanism in response to different environmental signals. Furthermore, our data are consistent with the notion that this regulatory overlap is mediated by changes in DNA supercoiling in response to these environmental stresses.

Hydrogenase synthesis in Bradyrhizobium japonicum Hupc mutants is altered in sensitivity to DNA gyrase inhibitors

In the Hupc mutants of Bradyrhizobium japonicum SR, regulation of expression of hydrogenase is altered; the mutants synthesize hydrogenase constitutively in the presence of atmospheric levels of oxygen. The DNA gyrase inhibitors nalidixic acid, novobiocin, and coumermycin were used to inhibit growth of wild-type and mutant cells. For each inhibitor tested, growth of mutant and wild-type strains was equally sensitive. However, in contrast to the wild type, the Hupc mutants synthesized hydrogenase in the presence of high levels of any inhibitor. Cells were incubated with the drugs and simultaneously labeled with 14C-labeled amino acids, and hydrogenase was immunoprecipitated with antibody to the large subunit of the enzyme. Fluorograms of antibody blots then were scanned to determine the relative amount of hydrogenase (large subunit) synthesized in the presence or absence of the gyrase inhibitors. The amount of hydrogenase synthesized by the Hupc mutants in the presence of 300 micrograms of nalidixic acid per ml was near the level of enzyme synthesized in the absence of the inhibitor. No hydrogenase was detected in antibody blots of wild-type cultures which were derepressed for hydrogenase in the presence of 100 micrograms of coumermycin or novobiocin per ml. In contrast, hydrogenase was synthesized by the Hupc mutants in the presence of 100 micrograms of either drug per ml. The amount synthesized ranged from 5 to 32% and 20 to 49%, respectively, of that in the absence of those inhibitors, but nevertheless, hydrogenase synthesis was detected in all of the mutants examined.(ABSTRACT TRUNCATED AT 250 WORDS)

Physiological and genetic responses of bacteria to osmotic stress

The capacity of organisms to respond to fluctuations in their osmotic environments is an important physiological process that determines their abilities to thrive in a variety of habitats. The primary response of bacteria to exposure to a high osmotic environment is the accumulation of certain solutes, K+, glutamate, trehalose, proline, and glycinebetaine, at concentrations that are proportional to the osmolarity of the medium. The supposed function of these solutes is to maintain the osmolarity of the cytoplasm at a value greater than the osmolarity of the medium and thus provide turgor pressure within the cells. Accumulation of these metabolites is accomplished by de novo synthesis or by uptake from the medium. Production of proteins that mediate accumulation or uptake of these metabolites is under osmotic control. This review is an account of the processes that mediate adaptation of bacteria to changes in their osmotic environment.

DNA supercoiling and the anaerobic and growth phase regulation of tonB gene expression

We show that several interacting environmental factors influence the topology of intracellular DNA. Negative supercoiling of DNA in vivo is increased by anaerobic growth and is also influenced by growth phase. The tonB promoter of Escherichia coli and Salmonella typhimurium was found to be highly sensitive to changes in DNA supercoiling. Expression was increased by novobiocin, an inhibitor of DNA gyrase, and was decreased by factors which increase DNA superhelicity. Expression of the plasmid-encoded tonB gene was enhanced by gamma delta insertions in cis in a distance- and orientation-independent fashion. Both the res site and the TnpR protein of gamma delta, which is known to function as a type I topoisomerase, were required for this activation. tonB expression increased during the growth cycle and was reduced by anaerobiosis. There was excellent correlation between tonB expression from a plasmid and the level of supercoiling of that plasmid under a wide range of conditions. The chromosomal tonB gene was regulated in a manner identical to that of the plasmid-encoded gene. Thus, the physiological regulation of tonB expression in response to anaerobiosis and growth phase appears to be mediated by environmentally induced changes in DNA superhelicity.