Phosphate starvation and low temperature as well as ultraviolet irradiation transcriptionally induce the Escherichia coli LexA-controlled gene sfiA

Regulation of phosphate starvation-specific responses in Escherichia coli

Toxic agents added into the medium of rapidly growing Escherichia coli induce specific stress responses through the activation of specialized transcription factors. Each transcription factor and downstream regulon (e.g. SoxR) are linked to a unique stress (e.g. superoxide stress). Cells starved of phosphate induce several specific stress regulons during the transition to stationary phase when the growth rate is steadily declining. Whereas the regulatory cascades leading to the expression of specific stress regulons are well known in rapidly growing cells stressed by toxic products, they are poorly understood in cells starved of phosphate. The intent of this review is to both describe the unique mechanisms of activation of specialized transcription factors and discuss signalling cascades leading to the induction of specific stress regulons in phosphate-starved cells. Finally, I discuss unique defence mechanisms that could be induced in cells starved of ammonium and glucose.

Interaction of RecA mediated SOS response with bacterial persistence, biofilm formation, and host response

Antibiotics have a primary mode of actions, and most of them have a common secondary mode of action via reactive species (ROS and RNS) mediated DNA damage. Bacteria have been able to tolerate this DNA damage by SOS (Save-Our-Soul) response. RecA is the universal essential key protein of the DNA damage mediated SOS repair in various bacteria including ESKAPE pathogens. In addition, antibiotics also triggers activation of various other bacterial mechanisms such as biofilm formation, host dependent responses, persister subpopulation formation. These supporting the survival of bacteria in unfriendly natural conditions i.e. antibiotic presence. This review highlights the detailed mechanism of RecA mediated SOS response as well as role of RecA-LexA interaction in SOS response. The review also focuses on inter-connection between DNA damage repair pathway (like SOS response) with other survival mechanisms of bacteria such as host mediated RecA induction, persister-SOS interplay, and biofilm-SOS interplay. This understanding of inter-connection of SOS response with different other survival mechanisms will prove beneficial in targeting the SOS response for prevention and development of therapeutics against recalcitrant bacterial infections. The review also covers the significance of RecA as a promising potent therapeutic target for hindering bacterial SOS response in prevailing successful treatments of bacterial infections and enhancing the conventional antibiotic efficiency.

Rapid evolution of acetic acid-detoxifying Escherichia coli under phosphate starvation conditions requires activation of the cryptic PhnE permease and induction of translesion synthesis DNA polymerases

Escherichia coli incubated in phosphate-limiting minimal medium dies during prolonged incubation as a result of the production of acetic acid. Variants that consume acetic acid generally sweep through the population after three serial cultures. Evolvability may primarily result from induction of the potentially mutagenic LexA DNA damage response or from growth of preexisting mutants. Cells starved of phosphate induce the LexA regulon through a unique mechanism based on an increase in the internal pH at the approach of the stationary phase. Evolved cells resume growth on phosphorylated products as a result of the activation of the cryptic PhnE permease. Here, it is shown that first PhnE-expressing revertants swept through starved populations independently of the expression of the LexA regulon. Induction of the LexA regulon and especially of the translesion synthesis DNA polymerases Pol IV and Pol V was, however, absolutely required for the ultimate evolution of acetic acid-detoxifying mutant strains. Both growth under selection and induction of translesion synthesis DNA polymerases are therefore required for adaptive evolution under phosphate starvation conditions.

The regulatory function of LexA is temperature-dependent in the deep-sea bacterium Shewanella piezotolerans WP3

The SOS response addresses DNA lesions and is conserved in the bacterial domain. The response is governed by the DNA binding protein LexA, which has been characterized in model microorganisms such as Escherichia coli. However, our understanding of its roles in deep-sea bacteria is limited. Here, the influence of LexA on the phenotype and gene transcription of Shewanella piezotolerans WP3 (WP3) was investigated by constructing a lexA deletion strain (WP3ΔlexA), which was compared with the wild-type strain. No growth defect was observed for WP3ΔlexA. A total of 481 and 108 genes were differentially expressed at 20 and 4°C, respectively, as demonstrated by comparative whole genome microarray analysis. Furthermore, the swarming motility and dimethylsulfoxide reduction assay demonstrated that the function of LexA was related to temperature. The transcription of the lexA gene was up-regulated during cold acclimatization and after cold shock, indicating that the higher expression level of LexA at low temperatures may be responsible for its temperature-dependent functions. The deep-sea microorganism S. piezotolerans WP3 is the only bacterial species whose SOS regulator has been demonstrated to be significantly influenced by environmental temperatures to date. Our data support the hypothesis that SOS is a formidable strategy used by bacteria against various environmental stresses.

Protective role of the RpoE (σE) and Cpx envelope stress responses against gentamicin killing of nongrowing Escherichia coli incubated under aerobic, phosphate starvation conditions

The viability of Escherichia coli starved of nitrogen (N) or phosphorus (P) decreased by up to seven orders of magnitude during prolonged incubation under aerobic conditions when exposed to high levels of the antibiotic gentamicin, whereas viability of cells starved of carbon (C) was barely affected. However, the initial rate of killing was lower for P-starved cells than for N-starved cells. The transient resistance of P-starved cells was partially dependent upon the expression of the phosphate (Pho) and Cpx responses. Constitutive activity of the Cpx and RpoE (σ(E)) envelope stress regulons increased the resistance of P- and N-starved cells. The level of expression of the RpoE regulon was fourfold higher in P-starved cells than in N-starved cell at the time gentamicin was added. Gentamicin killing of nongrowing cells may thus require ongoing aerobic glucose metabolism and faulty synthesis of structural membrane proteins. However, membrane protein damage induced by gentamicin can be eliminated or repaired by RpoE- and Cpx-dependent mechanisms pre-emptively induced in P-starved cells, which reveals a novel mechanism of resistance to gentamicin that is active in certain circumstances.

Filament formation by foodborne bacteria under sublethal stress

A number of studies have reported that pathogenic and nonpathogenic foodborne bacteria have the ability to form filaments in microbiological growth media and foods after prolonged exposure to sublethal stress or marginal growth conditions. In many cases, nucleoids are evenly spaced throughout the filamentous cells but septa are not visible, indicating that there is a blockage in the early steps of cell division but the mechanism behind filament formation is not clear. The formation of filamentous cells appears to be a reversible stress response. When filamentous cells are exposed to more favorable growth conditions, filaments divide rapidly into a number of individual cells, which may have major health and regulatory implications for the food industry because the potential numbers of viable bacteria will be underestimated and may exceed tolerated levels in foods when filamentous cells that are subjected to sublethal stress conditions are enumerated. Evidence suggests that filament formation under a number of sublethal stresses may be linked to a reduced energy state of bacterial cells. This review focuses on the conditions and extent of filament formation by foodborne bacteria under conditions that are used to control the growth of microorganisms in foods such as suboptimal pH, high pressure, low water activity, low temperature, elevated CO2 and exposure to antimicrobial substances as well as lack a of nutrients in the food environment and explores the impact of the sublethal stresses on the cell's inability to divide.

UV-C inactivation in Escherichia coli is affected by growth conditions preceding irradiation, in particular by the specific growth rate

AIMS

The objective was to analyse the impact of growth conditions, in particular of the specific growth rate, on the resistance of Escherichia coli towards UV-C irradiation.

METHODS AND RESULTS

Escherichia coli K12 wild-type bacteria (and in some experiments also a mutant not expressing RpoS, the global regulator of the general stress response; rpoS(-) mutant) were cultivated either in batch culture until stationary phase was reached or in continuous culture at different specific growth rates (μ) and then irradiated with UV-C light. Inactivation was determined by plating. The specific growth rate had a profound effect on UV-C resistance. Stationary phase or very slowly growing cells (0≤μ<0·1 h(-1)) as well as fast-growing cells exhibited a high resistance compared to bacteria growing at an intermediate rate (between 0·2 and 0·4 h(-1) ). The rpoS(-) mutant was more susceptible to UV irradiation than the wild-type when obtained from stationary phase, while mutant cells from continuous culture (μ=0·2 h(-1)) revealed a UV-C resistance similar to the wild-type grown under the same conditions.

CONCLUSIONS

Antecedent growth conditions determine the physiological state of bacteria including the resistance towards UV-C irradiation. In particular, the specific growth rate was shown to markedly affect UV-C resistance of E. coli. The observed pattern of UV-C resistance exhibiting a minimum at intermediate specific growth rates must be explained by two or several counteracting mechanisms. For lower specific growth rates, the regulator of the global stress response, RpoS, is at least partly involved in the physiological processes responsible for UV-C resistance.

SIGNIFICANCE AND IMPACT OF THE STUDY

The observed impact of antecedent growth conditions on UV-C resistance of E. coli stresses the necessity to use clearly defined cultivation conditions and to report them to gather meaningful and comparable data on the UV-C resistance of micro-organisms.

Binding sequences for RdgB, a DNA damage-responsive transcriptional activator, and temperature-dependent expression of bacteriocin and pectin lyase genes in Pectobacterium carotovorum subsp. carotovorum

Pectobacterium carotovorum subsp. carotovorum strain Er simultaneously produces the phage tail-like bacteriocin carotovoricin (Ctv) and pectin lyase (Pnl) in response to DNA-damaging agents. The regulatory protein RdgB of the Mor/C family of proteins activates transcription of pnl through binding to the promoter. However, the optimal temperature for the synthesis of Ctv (23 degrees C) differs from that for synthesis of Pnl (30 degrees C), raising the question of whether RdgB directly activates ctv transcription. Here we report that RdgB directly regulates Ctv synthesis. Gel mobility shift assays demonstrated RdgB binding to the P(0), P(1), and P(2) promoters of the ctv operons, and DNase I footprinting determined RdgB-binding sequences (RdgB boxes) on these and on the pnl promoters. The RdgB box of the pnl promoter included a perfect 7-bp inverted repeat with high binding affinity to the regulator (K(d) [dissociation constant] = 150 nM). In contrast, RdgB boxes of the ctv promoters contained an imperfect inverted repeat with two or three mismatches that consequently reduced binding affinity (K(d) = 250 to 350 nM). Transcription of the rdgB and ctv genes was about doubled at 23 degrees C compared with that at 30 degrees C. In contrast, the amount of pnl transcription tripled at 30 degrees C. Thus, the inverse synthesis of Ctv and Pnl as a function of temperature is apparently controlled at the transcriptional level, and reduced rdgB expression at 30 degrees C obviously affected transcription from the ctv promoters with low-affinity RdgB boxes. Pathogenicity toward potato tubers was reduced in an rdgB knockout mutant, suggesting that the RdgAB system contributes to the pathogenicity of this bacterium, probably by activating pnl expression.

Fur-dependent detoxification of organic acids by rpoS mutants during prolonged incubation under aerobic, phosphate starvation conditions

The activity of amino acid-dependent acid resistance systems allows Escherichia coli to survive during prolonged incubation under phosphate (P(i)) starvation conditions. We show in this work that rpoS-null mutants incubated in the absence of any amino acid survived during prolonged incubation under aerobic, P(i) starvation conditions. Whereas rpoS(+) cells incubated with glutamate excreted high levels of acetate, rpoS mutants grew on acetic acid. The characteristic metabolism of rpoS mutants required the activity of Fur (ferric uptake regulator) in order to decrease the synthesis of the small RNA RyhB that might otherwise inhibit the synthesis of iron-rich proteins. We propose that RpoS (sigma(S)) and the small RNA RyhB contribute to decrease the synthesis of iron-rich proteins required for the activity of the tricarboxylic acid (TCA) cycle, which redirects the metabolic flux toward the production of acetic acid at the onset of stationary phase in rpoS(+) cells. In contrast, Fur activity, which represses ryhB, and the lack of RpoS activity allow a substantial activity of the TCA cycle to continue in stationary phase in rpoS mutants, which decreases the production of acetic acid and, eventually, allows growth on acetic acid and P(i) excreted into the medium. These data may help explain the fact that a high frequency of E. coli rpoS mutants is found in nature.

The SOS response affects thermoregulation of colicin K synthesis

Temperature is one of the key environmental parameters affecting bacterial gene expression. This study investigated the effect of temperature on synthesis of Escherichia coli colicins E1, K, N and E7 as well as the molecular basis underlying thermoregulation of the colicin K activity gene cka. The results of our study show that synthesis of the investigated colicins is higher at 37 degrees C than at 22 degrees C and that temperature regulates cka expression at the level of transcription. We propose that the SOS response indirectly regulates thermoregulation of colicin K (and possibly of the other examined colicins). Two LexA dimers bind cooperatively with high affinity to the two overlapping LexA boxes in a temperature-independent manner. At 22 degrees C the relative degree of repression is higher as a result of less LexA cleavage due to a slower growth rate, while at 37 degrees C the extent of LexA cleavage is higher due to a higher growth rate. Thermoregulation of colicin synthesis is an additional example of the connection between the SOS regulon and cell physiology.

The lysine decarboxylase CadA protects Escherichia coli starved of phosphate against fermentation acids

Conflicting results have been reported for the rate and extent of cell death during a prolonged stationary phase. It is shown here that the viability of wild-type cells (MG1655) could decrease >or=10(8)-fold between days 1 and 14 and between days 1 and 6 of incubation under aerobic and anaerobic phosphate (P(i)) starvation conditions, respectively, whereas the cell viability decreased moderately under ammonium and glucose starvation conditions. Several lines of evidence indicated that the loss of viability of P(i)-starved cells resulted primarily from the catabolism of glucose into organic acids through pyruvate oxidase (PoxB) and pyruvate-formate lyase (PflB) under aerobic and anaerobic conditions, respectively. Weak organic acids that are excreted into the medium can reenter the cell and dissociate into protons and anions, thereby triggering cell death. However, P(i)-starved cells were efficiently protected by the activity of the inducible GadABC glutamate-dependent acid resistance system. Glutamate decarboxylation consumes one proton, which contributes to the internal pH homeostasis, and removes one intracellular negative charge, which might compensate for the accumulated weak acid anions. Unexpectedly, the tolerance of P(i)-starved cells to fermentation acids was markedly increased as a result of the activity of the inducible CadBA lysine-dependent acid resistance system that consumes one proton and produces the diamine cadaverine. CadA plays a key role in the defense of Salmonella at pH 3 but was thought to be ineffective in Escherichia coli since the protection of E. coli challenged at pH 2.5 by lysine is much weaker than the protection by glutamate. CadA activity was favored in P(i)-starved cells probably because weak organic acids slowly reenter cells fermenting glucose. Since the environmental conditions that trigger the death of P(i)-starved cells are strikingly similar to the conditions that are thought to prevail in the human colon (i.e., a combination of low levels of P(i) and oxygen and high levels of carbohydrates, inducing the microbiota to excrete high levels of organic acids), it is tempting to speculate that E. coli can survive in the gut because of the activity of the GadABC and CadBA glutamate- and lysine-dependent acid resistance systems.

SOS-independent induction of dinB transcription by beta-lactam-mediated inhibition of cell wall synthesis in Escherichia coli

Transcription of the dinB gene, encoding DNA polymerase IV, is induced by the inhibition of cell wall synthesis at different levels. Using the beta-lactam antibiotic ceftazidime, a PBP3 inhibitor, as a model, we have shown that this induction is independent of the LexA/RecA regulatory system. Induction of dinB transcription mediated by ceftazidime produces an increase in the reversion of a +1 Lac frameshift mutation.

The Escherichia coli SOS gene sbmC is regulated by H-NS and RpoS during the SOS induction and stationary growth phase

sbmC, an Escherichia coli gene, belongs to the SOS regulon, whose product is involved in cell susceptibility to microcin B17 and its expression is induced at the onset of the stationary growth phase. In the present work, we have investigated the regulation of sbmC expression during SOS induction and the stationary growth phase using a single-copy sbmC'-'lacZ fusion. The SOS induction of sbmC is profoundly diminished in the hns mutant and less diminished in the rpoS mutant. The strain with hns, rpoS double mutation, showed a similar level of sbmC induction to that of a strain with hns single mutation. Mutation in rpoS or hns causes the repression of the sbmC gene during the stationary growth phase. The sbmC expression in the rpoS mutant strain was approximately twofold lower than that in the hns mutant and the rpoS hns double mutant showed a similar level of sbmC expression to mutants deficient in rpoS alone. Interestingly, the sbmC'-'lacZ expression in the exponential growth phase was not derepressed in the hns mutant background. Transformation of hns and rpoS mutants with plasmids carrying histone-like nucleoid protein (H-NS) and RpoS effectively restored the sbmC expression to the wild-type level, respectively. The gel mobility shift assay showed that purified H-NS protein directly bound with a high affinity to a DNA fragment carrying the sbmC promoter region. These findings demonstrate that H-NS regulates the sbmC expression via H-NS's direct binding to the promoter region. In conclusion, our data suggest that H-NS and RpoS regulate a stationary phase-inducible sbmC gene in E. coli.

An aerobic recA-, umuC-dependent pathway of spontaneous base-pair substitution mutagenesis in Escherichia coli

Antimutator alleles indentify genes whose normal products are involved in spontaneous mutagenesis pathways. Mutant alleles of the recA and umuC genes of Escherichia coli, whose wild-type alleles are components of the inducible SOS response, were shown to cause a decrease in the level of spontaneous mutagenesis. Using a series of chromosomal mutant trp alleles, which detect point mutations, as a reversion assay, it was shown that the reduction in mutagenesis is limited to base-pair substitutions. Within the limited number of sites than could be examined, transversions at AT sites were the favored substitutions. Frameshift mutagenesis was slightly enhanced by a mutant recA allele and unchanged by a mutant umuC allele. The wild-type recA and umuC genes are involved in the same mutagenic base-pair substitution pathway, designated "SOS-dependent spontaneous mutagenesis" (SDSM), since a recAumuC strain showed the same degree and specificity of antimutator activity as either single mutant strain. The SDSM pathway is active only in the presence of oxygen, since wild-type, recA, and umuC strains all show the same levels of reduced spontaneous mutagenesis anaerobically. The SDSM pathway can function in starving/stationary cells and may, or may not, be operative in actively dividing cultures. We suggest that, in wild-type cells, SDSM results from basal levels of SOS activity during DNA synthesis. Mutations may result from synthesis past cryptic DNA lesions (targeted mutagenesis) and/or from mispairings during synthesis with a normal DNA template (untargeted mutagenesis). Since it occurs in chromosomal genes of wild-type cells, SDSM may be biologically significant for isolates of natural enteric bacterial populations where extended starvation is often a common mode of existence.

Non-growing Escherichia coli cells starved for glucose or phosphate use different mechanisms to survive oxidative stress

Recent data suggest that superoxide dismutases are important in preventing lethal oxidative damage of proteins in Escherichia coli cells incubated under aerobic, carbon starvation conditions. Here, we show that the alkylhydroperoxide reductase AhpCF (AHP) is specifically required to protect cells incubated under aerobic, phosphate (Pi) starvation conditions. Additional loss of the HP-I (KatG) hydroperoxidase activity dramatically accelerated the death rate of AHP-deficient cells. Investigation of the composition of spent culture media indicates that DeltaahpCF katG cells leak nutrients, which suggests that membrane lipids are the principal target of peroxides produced in Pi-starved cells. In fact, the introduction of various mutations inactivating repair activities revealed no obvious role for protein or DNA lesions in the viability of ahp cells. Because the death of ahp cells was directly related to ongoing aerobic glucose metabolism, we wondered how glycolysis, which requires free Pi, could proceed. 31P nuclear magnetic resonance spectra showed that Pi-starved cells consumed Pi but were apparently able to liberate Pi from phosphorylated products, notably through the synthesis of UDP-glucose. Whereas expression of the ahpCF and katG genes is enhanced in an OxyR-dependent manner in response to H2O2 challenge, we found that the inactivation of oxyR and both oxyR and rpoS genes had little effect on the viability of Pi-starved cells. In stark contrast, the inactivation of both oxyR and rpoS genes dramatically decreased the viability of glucose-starved cells.

Genetic variability and adaptation to stress

Besides an immediate cellular adaptation to stress, organisms can resist such challenges through changes in their genetic material. These changes can be due to mutation or acquisition of pre-evolved functions via horizontal transfer. In this chapter we will review evidence from bacterial genetics that suggests that the frequency of such events can increase in response to stress by activating mutagenic response (e.g. the SOS response) and by inhibiting antimutagenic activities (e.g. mismatch repair system, MRS). Natural selection, by favoring adaptations, can also select for the mechanism(s) that has/have generated the adaptive changes by hitchhiking. These mutator mechanisms can sometimes respond very specifically, though blindly, to the challenge of the environment. Such stress-induced increases in mutation rates enhance genetic polymorphism, which is the structural component of the barrier to genetic exchange. Since SOS and MRS are the enzymatic controls of this barrier, the modulation of these systems can lead to a burst of speciation.

Molecular keys to speciation: DNA polymorphism and the control of genetic exchange in enterobacteria

Speciation involves the establishment of genetic barriers between closely related organisms. The extent of genetic recombination is a key determinant and a measure of genetic isolation. The results reported here reveal that genetic barriers can be established, eliminated, or modified by manipulating two systems which control genetic recombination, SOS and mismatch repair. The extent of genetic isolation between enterobacteria is a simple mathematical function of DNA sequence divergence. The function does not depend on hybrid DNA stability, but rather on the number of blocks of sequences identical in the two mating partners and sufficiently large to allow the initiation of recombination. Further, there is no obvious discontinuity in the function that could be used to define a level of divergence for distinguishing species.

Characterization of Lactococcus lactis UV-sensitive mutants obtained by ISS1 transposition

Studies of cellular responses to DNA-damaging agents, mostly in Escherichia coli, have revealed numerous genes and pathways involved in DNA repair. However, other species, particularly those which exist under different environmental conditions than does E. coli, may have rather different responses. Here, we identify and characterize genes involved in DNA repair in a gram-positive plant and dairy bacterium, Lactococcus lactis. Lactococcal strain MG1363 was mutagenized with transposition vector pG+host9::ISS1, and 18 mutants sensitive to mitomycin and UV were isolated at 37 degrees C. DNA sequence analyses allowed the identification of 11 loci and showed that insertions are within genes implicated in DNA metabolism (polA, hexB, and deoB), cell envelope formation (gerC and dltD), various metabolic pathways (arcD, bglA, gidA, hgrP, metB, and proA), and, for seven mutants, nonidentified open reading frames. Seven mutants were chosen for further characterization. They were shown to be UV sensitive at 30 degrees C (the optimal growth temperature of L. lactis); three (gidA, polA, and uvs-75) were affected in their capacity to mediate homologous recombination. Our results indicate that UV resistance of the lactococcal strain can be attributed in part to DNA repair but also suggest that other factors, such as cell envelope composition, may be important in mediating resistance to mutagenic stress.

Control of the LexA regulon by pH: evidence for a reversible inactivation of the LexA repressor during the growth cycle of Escherichia coli

The LexA repressor controls the expression of several genes, including lexA, recA, and sfiA, which are induced when exponentially growing bacteria are exposed to DNA-damaging agents. Induction of this so-called SOS response takes place while LexA is cleaved in a reaction that requires the RecA protein and damaged DNA. We have shown that large fluctuations in the cellular concentration of the LexA repressor and in the rate of transcription of the sfiA gene also occur spontaneously during bacterial growth in complex medium such as LB. The possibility that changes in external or internal pH may explain these fluctuations has been explored. A consistent pattern was established whereby conditions leading to either increased or decreased pH were associated with altered expression of the lexA and sfiA genes. These data can be explained by a model in which the LexA repressor exists in either of two forms in equilibrium: a form favoured at homeostatic internal pH, which has a low affinity for the operators of LexA-controlled genes; and a form accumulated in response to a transient decrease in internal pH, which has a high affinity for operators.