The role of thiol redox systems in the peroxide stress response of Escherichia coli

The effect of mutations in the genes encoding glutathione, glutaredoxin, thioredoxin, and thioredoxin reductase on the response of growing Escherichia coli to oxidative stress was studied. The gshA mutants defective in glutathione synthesis had the lowest resistance to high doses of H2O2, whereas the trxB mutants defective in thioredoxin reductase synthesis had the highest resistance to this oxidant, exceeding that of the parent strain. Among the studied mutants, the trxB cells demonstrated the highest basic levels of catalase activity and intracellular glutathione; they were able to rapidly reach the normal GSH level after oxidative stress. At the same time, these bacteria showed high frequency of induced mutations. The expression of the katG and sulA genes suggests that, having different sensitivity to high oxidant concentrations, the studied mutants differ primarily in their ability to induce the antioxidant genes of the OxyR and SOS regulons.     

The role of thiol redox systems in the resistance of <Emphasis Type="Italic">Escherichia coli</Emphasis> in the stationary phase

The effect of glutathione (gshA), thioredoxin (trxA), and thioredoxin reductase (trxB) mutations on the adaptation of Escherichia coli to prolonged glucose starvation was investigated. The trxB mutation had the worst consequences for the stationary-phase cells. These bacteria exhibited decreased survival, increased sensitivity to oxidants, and decreased expression of the katE and sulA genes. As the stationary phase proceeded, the physiological resistance to antibiotics increased in all the strains tested; however, the thiol redox system mutants were far less able to develop antibiotic resistance than the parent strain cells. During the stationary phase, a considerable shift was observed in the redox status of intra- and extracellular glutathione toward the oxidative values. These results indicate that the thiol redox systems play an important role in the adaptation of Escherichia coli to prolonged starvation and antibiotic resistance.     

The Escherichia coli histone-like protein HU has a role in stationary phase adaptive mutation

Stationary phase adaptive mutation in Escherichia coli is thought to be a mechanism by which mutation rates are increased during stressful conditions, increasing the possibility that fitness-enhancing mutations arise. Here we present data showing that the histone-like protein, HU, has a role in the molecular pathway by which adaptive Lac(+) mutants arise in E. coli strain FC40. Adaptive Lac(+) mutations are largely but not entirely due to error-prone DNA polymerase IV (Pol IV). Mutations in either of the HU subunits, HUalpha or HUbeta, decrease adaptive mutation to Lac(+) by both Pol IV-dependent and Pol IV-independent pathways. Additionally, HU mutations inhibit growth-dependent mutations without a reduction in the level of Pol IV. These effects of HU mutations on adaptive mutation and on growth-dependent mutations reveal novel functions for HU in mutagenesis.     

Evolutionary cheating in Escherichia coli stationary phase cultures

Starved cultures of Escherichia coli are highly dynamic, undergoing frequent population shifts. The shifts result from the spread of mutants able to grow under conditions that impose growth arrest on the ancestral population. To analyze competitive interactions underlying this dynamic we measured the survival of a typical mutant and the wild type during such population shifts. Here we show that the survival advantage of the mutant at any given time during a takeover is inversely dependent on its frequency in the population, its growth adversely affects the survival of the wild type, and its ability to survive in stationary phase at fixation is lower than that of its ancestor. These mutants do not enter, or exit early, the nondividing stationary-phase state, cooperatively maintained by the wild type. Thus they end up overrepresented as compared to their initial frequency at the onset of the stationary phase, and subsequently they increase disproportionately their contribution in terms of progeny to the succeeding generation in the next growth cycle, which is a case of evolutionary cheating. If analyzed through the game theory framework, these results might be explained by the prisoner's dilemma type of conflict, which predicts that selfish defection is favored over cooperation.     

Identification and characterization of stationary phase inducible genes in Escherichia coli

During transition into stationary phase a large set of proteins is induced in Escherichia coli. Only a minority of the corresponding genes has been identified so far. Using the λplacMu system and a plate screen for carbon starvation-induced fusion activity, a series of chromosomal lacZ fusions (csi::lacZ) was isolated. In complex medium these fusions were induced either during late exponential phase or during entry into stationary phase. csi::lacZ expression in minimal media in response to starvation for carbon, nitrogen and phosphate sources and the roles of global regulators such as the alternative sigma factor sigma;^S (encoded by rpoS), cAMP/CRP and the relA gene product were investigated. The results show that almost every fusion exhibits its own characteristic pattern of expression, suggesting a complex control of stationary phase-inducible genes that involves various combinations of regulatory mechanisms for different genes. All fusions were mapped to the E. coli chromosome. Using fine mapping by Southern hybridization, cloning, sequencing and/or phenotypic analysis, csi-5, csi-17, and csi-18 could be localized in osmY (encoding a periplasmic protein), glpD (aerobic glycerol-3-phosphate dehydrogenase) and glgA (glycogen synthase), respectively. The other fusions seem to specify novel genes now designated csiA through to csiF. csi-17(glpD)::lacZ was shown to produce its own glucose-starvation induction, thus illustrating the Intricacies of gene-fusion technology when applied to the study of gene regulation.     

The role of redox in the regulation of manganese-containing superoxide dismutase biosynthesis in Escherichia coli

The manganese-containing superoxide dismutase in Escherichia coli is an inducible enzyme that protects cells against oxygen toxicity. The manganese-enzyme is induced by oxygen, nitrate, redox active compounds that react with oxygen to generate superoxide radicals, as well as iron chelators. In order to test the hypothesis that the redox state of the cell is involved in regulating manganese-superoxide dismutase biosynthesis, we studied the effects of several oxidants on growth and superoxide dismutase biosynthesis. The data showed, that under anaerobic conditions, the active manganese-enzyme is induced in the presence of potassium ferricyanide, copper-cyanide complex, ammonium persulfate, and hydrogen peroxide. Western blot analysis revealed that the induction of manganese-superoxide dismutase by the oxidants is associated with de novo protein biosynthesis. Potassium ferricyanide and hydrogen peroxide induced the enzyme under aerobic conditions as well. It is concluded that the redox state of the cell possibly influences the biosynthesis and/or activity of an iron-containing repressor protein that serves to negatively regulate manganese-superoxide dismutase biosynthesis.     

Escherichia coli produces linoleic acid during late stationary phase.

Escherichia coli produces linoleic acid in the late stationary phase. This was the case whether the cultures were grown aerobically or anaerobically on a supplemented glucose-salts medium. The linoleic acid was detected by thin-layer chromatography and was measured as the methyl ester by gas chromatography. The linoleic acid methyl ester was identified by its mass spectrum. Lipids extracted from late-stationary-phase cells generated thiobarbituric acid-reactive carbonyl products when incubated with a free radical initiator. In contrast, extracts from log-phase or early-stationary-phase cells failed to do so, in accordance with the presence of polyunsaturated fatty acid only in the stationary-phase cells.     

A role for the umuDC gene products of Escherichia coli in increasing resistance to DNA damage in stationary phase by inhibiting the transition to exponential growth

The umuDC gene products, whose expression is induced by DNA-damaging treatments, have been extensively characterized for their role in SOS mutagenesis. We have recently presented evidence that supports a role for the umuDC gene products in the regulation of growth after DNA damage in exponentially growing cells, analogous to a prokaryotic DNA damage checkpoint. Our further characterization of the growth inhibition at 30 degrees C associated with constitutive expression of the umuDC gene products from a multicopy plasmid has shown that the umuDC gene products specifically inhibit the transition from stationary phase to exponential growth at the restrictive temperature of 30 degrees C and that this is correlated with a rapid inhibition of DNA synthesis. These observations led to the finding that physiologically relevant levels of the umuDC gene products, expressed from a single, SOS-regulated chromosomal copy of the operon, modulate the transition to rapid growth in E. coli cells that have experienced DNA damage while in stationary phase. This activity of the umuDC gene products is correlated with an increase in survival after UV irradiation. In a distinction from SOS mutagenesis, uncleaved UmuD together with UmuC is responsible for this activity. The umuDC-dependent increase in resistance in UV-irradiated stationary-phase cells appears to involve, at least in part, counteracting a Fis-dependent activity and thereby regulating the transition to rapid growth in cells that have experienced DNA damage. Thus, the umuDC gene products appear to increase DNA damage tolerance at least partially by regulating growth after DNA damage in both exponentially growing and stationary-phase cells.     

Escherichia coli deltafur mutant displays low HPII catalase activity in stationary phase

Iron is among the most important micronutrients used by bacteria. As a partner of the Fenton reaction, however, iron potentiates oxygen toxicity. Strict regulation of iron metabolism, and its coupling with regulation of defenses against oxidative stress, is an essential factor for life in the presence of oxygen. In Escherichia coli, iron metabolism is regulated by the Fur protein. A Fur-deficient mutant, in stationary phase, displayed about 30y-fold lower HPII activity than the respective, Fur-proficient parental strain. Deletion of fur seems to affect HPII catalase specifically, since the mutant was capable of inducing HPI catalase when challenged with H(2)O(2). Low HPII catalase activity appears to be among the reasons for hydrogen peroxide hypersensitivity of the deltafur mutant.     

The role of thiol redox systems in the peroxide stress response of <Emphasis Type="Italic">Escherichia coli</Emphasis>

The effect of mutations in the genes encoding glutathione, glutaredoxin, thioredoxin, and thioredoxin reductase on the response of growing Escherichia coli to oxidative stress was studied. The gshA mutants defective in glutathione synthesis had the lowest resistance to high doses of H₂O₂, whereas the trxB mutants defective in thioredoxin reductase synthesis had the highest resistance to this oxidant, exceeding that of the parent strain. Among the studied mutants, the trxB cells demonstrated the highest basic levels of catalase activity and intracellular glutathione; they were able to rapidly reach the normal GSH level after oxidative stress. At the same time, these bacteria showed high frequency of induced mutations. The expression of the katG and sulA genes suggests that, having different sensitivity to high oxidant concentrations, the studied mutants differ primarily in their ability to induce the antioxidant genes of the OxyR and SOS regulons.     

Effect of sigmaS on sigmaE-directed cell lysis in Escherichia coli early stationary phase

The sigmaE regulon has been shown to perform a novel function that causes dead-cell lysis specific to the early stationary phase in addition to its well-known role in the extracytoplasmic stress response in Escherichia coli. Here, the effect of sigmaS as a general stress-responsive sigma factor on sigmaE-directed cell lysis was investigated. The lysis phenomena were observed in both rpoS mutant and parental strains constitutively expressing active sigmaE, but the former lysis occurred at a relatively early stage compared to the latter. Based on these results and experiments with hydrogen peroxide, we propose that some stresses generate living but non-culturable cells, which are subject to sigmaE-directed cell lysis.     

Uncoupler resistance in Escherichia coli: the role of cellular respiration

Bioenergetic properties of a mutant strain of Escherichia coli K12 designated TUV, which is resistant to the protonophoric uncoupling agent 4,5,6,7-tetrachloro-2-trifluoromethylbenzimidiazole (TTFB) have been compared with those of its non-resistant parent, E. coli K12 Doc-S. Strain TUV grew and respired some 20-30% faster than strain Doc-S, and was cross-resistant to carbonylcyanide p-(trifluoromethoxy)phenylhydrazone and triphenyltin, but not to 2,4-dinitrophenol. Phosphorus nuclear magnetic resonance demonstrated the TTFB-mediated collapse of the transmembrane pH gradient at identical rates in starved cells of both strains, indicating that uncoupler access and function were unimpaired in the mutant under these conditions. Strain TUV displayed enhanced uncoupler resistance and maintained intracellular pH and ATP levels only when respiring. On the other hand, strain TUV also showed increased resistance to novobiocin, implying that its outer wall permeability had been lowered. We suggest that the active resistance of strain TUV results from the exclusion of uncoupler by the interaction of inner and outer membrane components in a manner modulated by the degree of cellular energization.     

Enhanced fitness of recombinant protein synthesis in the stationary phase of Escherichia coli batch cultures

The ability to synthesize both recombinant and homologous cell proteins has been studied during the stationary phase of E. coli batch cultures. The anabolic potential of the culture dramatically decreases when entering into the stationary phase but slightly recovers several hours latter. In addition, CI857-controlled production of -galactosidase is transiently enhanced at late stages of the stationary phase. These results show a non-synchronous distribution of the biosynthetic resources throughout culture growth phases, favouring the production of recombinant proteins in both exponentially growing and aged, stationary cells.     

surA, an Escherichia coli gene essential for survival in stationary phase.

Mutations in genes not required for exponential growth but essential for survival in stationary phase were isolated in an effort to understand the ability of wild-type Escherichia coli cells to remain viable during prolonged periods of nutritional deprivation. The phenotype of these mutations is referred to as Sur- (survival) and the genes are designated sur. The detailed analysis of one of these mutations is presented here. The mutation (surA1) caused by insertion of a mini-Tn10 element defined a new gene located near 1 min on the E. coli chromosome. It was located directly upstream of pdxA and formed part of a complex operon. Evidence is presented supporting the interpretation that cells harboring the surA1 mutation die during stationary phase while similar insertion mutations in other genes of the operon do not lead to a Sur- phenotype. Strains harboring surA1 had a normal doubling time in both rich and minimal medium, but cultures lost viability after several days in stationary phase. Analysis of revertants and suppressors of surA1, which arose after prolonged incubation in stationary phase, indicates that DNA rearrangements (excisions and duplications) occurred in cultures of this strain even when the viable-cell counts were below 10(2) cells per ml. Cells containing suppressing mutations then grew in the same culture to 10(8) cells per ml, taking over the population. The implications of these observations to our understanding of stationary-phase mutagenesis are discussed.     

The role of thiol redox systems in the response of <Emphasis Type="Italic">Escherichia coli</Emphasis> to far-UV irradiation

Escherichia coli mutants deficient in glutathione (gshA), glutaredoxin (grxA), thioredoxin (trxA), and thioredoxin reductase (trxB) synthesis were studied with respect to their resistance to far-UV (UV₂₅₄) exposure. The trxA, trxB, and grxA mutants subjected to a short-term UV exposure were found to be more resistant to UV irradiation than the parent cells. Under the same conditions, the trxA and trxB mutants demonstrated a high level of induction of the sulA gene, a component of the SOS regulon. The mutagenic effect of long-term UV exposure of all the mutants with redox deficiencies was more pronounced than in the case of the parent strain, and the trxA and trxB mutants were found to be the least viable microorganisms. Pretreatment of the cells with low concentrations of the thiol-oxidizing agent diamide enhanced the sulA gene expression; however, high concentrations of diamide inhibited sulA expression. The data obtained indicate that the thiol redox systems of E. coli are involved in its response to far-UV irradiation.     

Nonequilibrium thermodynamics of thiol/disulfide redox systems: a perspective on redox systems biology

Understanding the dynamics of redox elements in biologic systems remains a major challenge for redox signaling and oxidative stress research. Central redox elements include evolutionarily conserved subsets of cysteines and methionines of proteins which function as sulfur switches and labile reactive oxygen species (ROS) and reactive nitrogen species (RNS) which function in redox signaling. The sulfur switches depend on redox environments in which rates of oxidation are balanced with rates of reduction through the thioredoxins, glutathione/glutathione disulfide, and cysteine/cystine redox couples. These central couples, which we term redox control nodes, are maintained at stable but nonequilibrium steady states, are largely independently regulated in different subcellular compartments, and are quasi-independent from each other within compartments. Disruption of the redox control nodes can differentially affect sulfur switches, thereby creating a diversity of oxidative stress responses. Systems biology provides approaches to address the complexity of these responses. In the present review, we summarize thiol/disulfide pathway, redox potential, and rate information as a basis for kinetic modeling of sulfur switches. The summary identifies gaps in knowledge especially related to redox communication between compartments, definition of redox pathways, and discrimination between types of sulfur switches. A formulation for kinetic modeling of GSH/GSSG redox control indicates that systems biology could encourage novel therapeutic approaches to protect against oxidative stress by identifying specific redox-sensitive sites which could be targeted for intervention.