Glutathione-dependent conversion of N-ethylmaleimide to the maleamic acid by Escherichia coli: an intracellular detoxification process.

The electrophile N-ethylmaleimide (NEM) elicits rapid K(+) efflux from Escherichia coli cells consequent upon reaction with cytoplasmic glutathione to form an adduct, N-ethylsuccinimido-S-glutathione (ESG) that is a strong activator of the KefB and KefC glutathione-gated K(+) efflux systems. The fate of the ESG has not previously been investigated. In this report we demonstrate that NEM and N-phenylmaleimide (NPM) are rapidly detoxified by E. coli. The detoxification occurs through the formation of the glutathione adduct of NEM or NPM, followed by the hydrolysis of the imide bond after which N-substituted maleamic acids are released. N-ethylmaleamic acid is not toxic to E. coli cells even at high concentrations. The glutathione adducts are not released from cells, and this allows glutathione to be recycled in the cytoplasm. The detoxification is independent of new protein synthesis and NAD(+)-dependent dehydrogenase activity and entirely dependent upon glutathione. The time course of the detoxification of low concentrations of NEM parallels the transient activation of the KefB and KefC glutathione-gated K(+) efflux systems.

Rapid inactivation of the Escherichia coli Kdp K+ uptake system by high potassium concentrations.

The Kdp K+ uptake system of Escherichia coli is induced by limitation for K+ and/or high osmolarity. In the present study, the regulation of the activity of the Kdp system has been investigated in E. coli mutants possessing only the Kdp system as the mechanism of K+ accumulation. Cells grown in the presence of low K+ (0.1-1 mM) exhibit normal growth. However, growth inhibition results from exposure of cells to moderate levels of external K+ (> 5 mM). Measurement of the cytoplasmic pH, of K+ pools and of transport via the Kdp system demonstrates that the Kdp system is rapidly and irreversibly inhibited by moderate external K+. Concentrations of K+ greater than 2 mM are sufficient to cause inhibition of Kdp. At pH 6, this results in rapid lowering of the capacity for pH homeostasis, but at pH 7 the intracellular pH is unaffected. Parallel analysis of the expression of the Kdp system in a Kdp+/kdpFABC-lacZ strain shows that levels of K+ that are sufficient to inhibit Kdp activity also repress expression. As a result, growth inhibition of strains solely possessing Kdp arises jointly from inhibition of Kdp activity and repression of Kdp gene expression. These data identify an important aspect of the regulation of potassium transport via the Kdp system and also provide support for a model of regulation of Kdp expression via at least two mechanisms: sensing of both turgor and external K+ concentration.

Perturbation of anion balance during inhibition of growth of Escherichia coli by weak acids.

During inhibition of cell growth by weak acids, there is substantial accumulation of the weak acid anions in the cytoplasm. This study was undertaken to determine the impact of anion accumulation on cellular pools. At pH 6, growth in the presence of 8 mM acetate led to an internal pool of greater than 240 mM acetate anion and resulted in reduced levels of glutamate in the cell, but there were no significant changes in K+ and Na+ levels. At low osmolarity, the change in the glutamate pool compensated for only a small fraction of the accumulated acetate anion. However, at high osmolarity, glutamate compensated for over half of the accumulated acetate. Recovery of the normal cytoplasmic pH after the removal of acetate was dependent on the synthesis of glutamate.

Survival during exposure to the electrophilic reagent N-ethylmaleimide in Escherichia coli: role of KefB and KefC potassium channels.

The role of the KefB and KefC potassium efflux systems in protecting Escherichia coli cells against the toxic effects of the electrophile N-ethylmaleimide has been investigated. Activation of KefB and KefC aids the survival of cells exposed to high concentrations (> 100 microM) of NEM. High potassium concentrations reduce the protection afforded by activation of KefB and KefC, but the possession of these systems is still important under these conditions. The Kdp system, which confers sensitivity to the electrophile methylglyoxal, did not affect the survival of cells exposed to NEM. Survival is correlated with the reduction of the cytoplasmic pH upon activation of the channels. In particular, the kinetics of the intracellular pH (pHi) change are crucial to the retention of viability of cells exposed to NEM; slow acidification does not protect cells as effectively as rapid lowering of pHi. Cells treated with low levels of NEM (10 microM) recover faster if they activate KefB and KefC, and this correlates with changes in pHi. The pHi does not significantly alter the rate of NEM metabolism. The possible mechanisms by which protection against the electrophile is mediated are discussed.

Potassium channel activation by glutathione-S-conjugates in Escherichia coli: protection against methylglyoxal is mediated by cytoplasmic acidification.

Escherichia coli possesses two glutathione-gated potassium channels, KefB and KefC, that are activated by glutathione-S-conjugates formed with methylglyoxal. We demonstrate that activation of the channels leads to cytoplasmic acidification and that this protects cells during electrophilic attack. Further, we demonstrate that mutants lacking the channels can be protected against the lethal effects of methylglyoxal by acidification of the cytoplasm with a weak acid. The degree of protection is determined by the absolute value of the pHi and the time at which acidification takes place. Alterations in the pHi do not accelerate the rate of detoxification of methylglyoxal. The mechanism by which methylglyoxal causes cell death and the implications for pHi-mediated resistance to methylglyoxal are discussed.

The role of peptide metabolism in the growth of Listeria monocytogenes ATCC 23074 at high osmolarity.

The growth of Listeria monocytogenes ATCC 23074 in defined medium is sensitive to high osmolarity when compared with its growth in complex media, such as brain heart infusion (BHI). The two major contributors to this difference in growth rate are the availability in BHI of the osmoprotectant glycine betaine and peptides. Peptone plays two major roles: firstly as a nutritional supplement for protein synthesis, and secondly as a source of amino acids and peptides that serve as a mechanism of maintaining turgor. In the presence of peptone the total amino acid pool at high osmolarity is substantial and even in the presence of glycine betaine the amino acid pool makes a major contribution to turgor maintenance. At high osmolarity there is a general increase in amino acid pools, with particularly substantial pools of glutamate, aspartate, proline, hydroxyproline and glycine. Peptides are also accumulated by cells from the peptone supplied in the medium. Glycine-containing peptides are accumulated in the cytoplasm under all conditions. Specific glycine- and proline-containing peptides stimulate growth at high osmolarity. The peptide prolyl-hydroxyproline accumulates in cells to high levels in response to growth at high osmolarity, and the pools of the derived amino acids also show a dependence on the external osmotic pressure. However, proline only confers significant osmoprotection when supplied as peptides. The significance of these data in the context of the occurrence of L. monocytogenes in foods with high peptide content is discussed.

The K(+)-efflux system, KefC, in Escherichia coli: genetic evidence for oligomeric structure.

KefC is a glutathione-gated K(+)-efflux system that is widespread in Gram-negative bacteria and which plays a role in the protection of cells from the toxic effects of electrophilic reagents, such as N-ethylmaleimide (NEM). The KefC gene from Escherichia coli has been cloned and the DNA sequenced. A number of kefC mutants that affect K+ retention by the KefC system have been isolated and all retain activation by NEM. Cloned kefC was found to suppress the phenotype of two such mutants kefC121 and kefC103. Analysis of this phenomenon has shown that suppression is specific to the KefC system, but that cloned kefC from Klebsiella and Erwinia can also mediate suppression of the mutant phenotype. Plasmid constructs of the E. coli gene in which expression of the cloned gene was diminished showed induced ability to suppress the mutant phenotype. KefC'-'LacZ hybrid proteins were inserted in the membrane but did not suppress the mutant phenotype. Cloned kefC did not suppress a mutant kefB allele that exhibited a similar phenotype to the kefC121 allele. These data suggest that suppression is unlikely to arise from exclusion of the mutant form of the protein from the membrane. Furthermore, NEM-activated K+ efflux from a strain carrying both the mutant and cloned wild-type alleles was faster than when either allele was present in cells alone, suggesting that both forms of the protein are inserted into the membrane. These data are discussed in terms of a model for the KefC protein in which the protein is composed of one or more identical subunits that interact in the membrane.

Interdependence of K+ and glutamate accumulation during osmotic adaptation of Escherichia coli.

Escherichia coli responds to an increase in medium osmolarity by accumulating K+ and glutamate. At low osmolarity a large fraction of cytoplasmic K+ serves to balance charge on macromolecular anions. That fraction of K+ is here referred to as "bound," as distinguished from "free" K+ that serves to balance charge of small anions. At higher osmolarity where cytoplasmic K+ increases markedly, the bound fraction decreases but the absolute amount of bound K+ expressed per unit of dry weight increases. The increase in bound K+ can be explained largely by the reduction of cytoplasmic putrescine at high osmolarity. At high osmolarity, glutamate is the major cytoplasmic anion, equal to at least 70% of free cytoplasmic K+. A sudden increase in the osmolarity of the medium stimulates glutamate synthesis with a lag of only about a minute; glutamate synthesis is almost totally dependent on K+ uptake. The high rate of flow of nitrogen through the glutamate pool under control conditions of growth at low osmolarity indicates that glutamate accumulation immediately after shift to high osmolarity must be due to inhibition of utilization of glutamate in the synthesis of other nitrogen-containing compounds rather than stimulation of glutamate synthesis. In agreement with this reasoning we find the kinetics of glutamate accumulation to be independent of the specific path of synthesis, whether by glutamate dehydrogenase or by glutamate synthase. Synthesis of glutamate appears to be required to attain normal values of the electrical membrane potential after shift to high osmolarity.

Activation of potassium channels during metabolite detoxification in Escherichia coli.

In bacteria the detoxification of compounds as diverse as methylglyoxal and chlorodinitrobenzene proceeds through the formation of a glutathione adduct. In the Gram-negative bacteria, e.g. Escherichia coli, such glutathione adducts activate one, or both, of a pair of potassium efflux systems KefB and KefC. These systems share many of the properties of cation-translocating channels in eukaryotes. The activity of these systems has been found to be present in a range of Gram-negative bacteria, but not in the glutathione-deficient species of Gram-positive organisms. The conservation of the activity of these systems in a diverse range of organisms suggested a physiological role for these systems. Here we demonstrate that in E. coli cells activation of the KefB efflux system is essential for the survival of exposure to methylglyoxal. Methylglyoxal can be added to the growth medium or its synthesis can be stimulated in the cytoplasm. Under both sets of conditions survival is aided by the activity of KefB. Inhibition of KefB activity by the addition of 10 mM potassium to the growth medium stimulates methylglyoxal-induced cell death. This establishes an essential physiological function for the KefB system.

Escherichia coli accumulates the eukaryotic osmolyte taurine at high osmolarity.

Escherichia coli accumulated taurine at high osmolarity via the ProU and ProP transport systems. Taurine accumulation was shown to be osmotically active as it displaced cytoplasmic K+. In contrast to betaine and proline, taurine only modestly enhanced the growth rate of E. coli at high osmolarity and only if the cell was unable to synthesise trehalose. These studies show that taurine cannot be used as a tracer for the extra-cytoplasmic space of bacteria grown at high osmolarity.

The gdhA gene is located at 38.6 minutes on the Escherichia coli map.

We report here that the gdhA gene of Escherichia coli, which encodes the NADP-specific glutamate dehydrogenase, is located at 38.6 min on the map. We have confirmed this location by showing linkage with three Tn10 insertions that are linked to the aroD, pheS, and ansA loci, by complementation by a restriction-mapped lambda clone, and by showing correspondence between the restriction maps of the chromosome and the cloned and sequenced gdhA gene.

Involvement of gamma-glutamyl peptides in osmoadaptation of Escherichia coli.

Accumulation of K+ ions and glutamate plays a primary role in maintaining osmotic balance in Escherichia coli, as illustrated by the high concentrations of these ions present in cells growing in medium of high osmolality. We found that two gamma-glutamyl peptides and glutamine also accumulated during growth at high osmolarity. In a mutant unable to make trehalose growing in 1.3 osM medium, glutathione, gamma-glutamylglutamine, and glutamine accumulated to levels of 73, 33, and 140 mumol/g of protein, respectively. In such cells, K+ was present at 1,450 mumol/g of protein, indicating that glutathione and gamma-glutamylglutamine accounted for less than 10% of the low-molecular-weight anions accumulated with K+. However, glutathione is needed for wild-type osmotolerance in this species. A mutant deficient in glutathione because of an insertion in the gshA gene was unable to grow above 1.4 osM, grew more slowly at intermediate osmolarities, and took longer to adapt to growth following osmotic upshock. The involvement of glutathione in osmoregulation was independent of the effect of glutathione on K+ retention.

Chloride transport pathways and their bioenergetic implications in the obligate acidophile Bacillus coagulans.

The protonophore-mediated collapse of the large delta pH that acidophiles maintain across their cytoplasmic membranes was augmented by the presence of Cl-, and Cl- influx into the cells occurred evidently in response to the protonophore-induced increase in the inside-positive membrane potential (+ delta psi). In respiring cells, the addition of Cl- but not SO4(2-) salts caused a rapid and precipitous decrease in the + delta psi. A Nernstian relationship between the imposed transmembrane K+ gradient and the valinomycin-induced K+ diffusion potentials was observed when everted membrane vesicles were loaded with K2SO4 or KH2PO4 but not when loaded with KCl or KNO3. Thus, electrogenic Cl- transport occurred in Bacillus coagulans. In addition, a nonelectrogenic temperature-sensitive Cl- transport mechanism, with the net Cl- efflux coefficient (PCl-) ranging from 1.5 x 10(-4) to 6.1 x 10(-6) cm/s, accounted for the massive Cl- efflux from Cl(-)-loaded cells. Thus, B. coagulans, despite its dependence on the + delta psi and therefore the need to exclude anions, apparently possesses specific mechanisms for Cl- permeation. Active cells of B. coagulans prevented Cl- accumulation from attaining an electrochemical equilibrium, maintaining a delta micro Cl- of ca. -63 mV. B. coagulans therefore also possesses an energy-dependent mechanism for Cl- exclusion from the cells.

Electron spin resonance measurements of the effect of ionophores on the transmembrane pH gradient of an acidophilic bacterium.

The delta pH in ionophore-treated cells of an acidophile has been determined by electron spin resonance spectroscopy. The values obtained were comparable to those obtained using the more conventional techniques involving radiolabeled probes. No binding of the spin-labeled probe was observed as determined by two independent control experiments and by the characteristics of the probe signal. These results led us to conclude that the delta pH measured in protonophore/ionophore-treated cells is a result of a Donnan potential, which may be a physical property of all intact bacterial cells at low pH values.