Interaction of E. coli cells with ascorbic acid and sodium nitrite studied by ESR method]

Ascorbic acid, an effective modulator and regulator of cell metabolism, was shown to induce the production of nitric oxide in E. coli cells. This process was detected by EPR spectroscopy as the generation of a spectral signal typical of nitrosyl-iron-sulfur centers (Fe-S-NO) under anaerobic conditions. Incubation of E. coli cells in the presence of ascorbic acid under aerobic conditions was shown to be accompanied by sodium nitrite formation. It is suggested that ascorbic acid is capable of supporting the system of energy supply to cells in hypoxia caused by reduced oxygen content or treatment with sodium nitrite.     

Aerobic nitrate and nitrite reduction in continuous cultures of Escherichia coli E4

Nitrate and nitrite was reduced by Escherichia coli E4 in a l-lactate (5 mM) limited culture in a chemostat operated at dissolved oxygen concentrations corresponding to 90–100% air saturation. Nitrate reductase and nitrite reductase activity was regulated by the growth rate, and oxygen and nitrate concentrations. At a low growth rate (0.11 h^–1) nitrate and nitrite reductase activities of 200 nmol · mg^–1 protein · min^–1 and 250 nmol · mg^–1 protein · min^–1 were measured, respectively. At a high growth rate (0.55 h^–1) both enzyme activities were considerably lower (25 and 12 nmol mg^–1 · protein · min^–1). The steady state nitrite concentration in the chemostat was controlled by the combined action of the nitrate and nitrite reductase. Both nitrate and nitrite reductase activity were inversely proportional to the growth rate. The nitrite reductase activity decreased faster with growth rate than the nitrate reductase. The chemostat biomass concentration of E. coli E4, with ammonium either solely or combined with nitrate as a source of nitrogen, remained constant throughout all growth rates and was not affected by nitrite concentrations. Contrary to batch, E. coli E4 was able to grow in continuous cultures on nitrate as the sole source of nitrogen. When cultivated with nitrate as the sole source of nitrogen the chemostat biomass concentration is related to the activity of nitrate and nitrite reductase and hence, inversely proportional to growth rate.     

Non-Enzymatic Reduction of Nitrite by Means of Ascorbic Acid in Citrus and Other Higher Plant Tissues

It has been proved that the nitrite reduction in the leaves and other plant tissues of citrus and other green plants is partly or mainly a non-enzymatic chemical process, and a heat-stable factor present in these tissues is responsible for this reduction. It is suggested that ascorbic acid plays a major role in this chemical reaction since the reduction is inhibited by ascorbic acid oxidase. A significant association was also found between the ascorbic acid content and the nitrite reduction capacity of citrus leaves. Evidence has been presented that this non-enzymatic chemical reduction of nitrite occurs also in vivo as undetached citrus leaves on branches placed in NaNO₂ solution have shown diminution of their ascorbic acid content along with the absorption of nitrite. Stronger accumulation of nitrite in these leaf tissues was observed under dark conditions, apparently due to the inhibition of the biosynthesis of the ascorbic acid.     

Copper- and Arene-Catalyzed Cleavage of DNA

DNA was found to be cleaved by arenes and copper(II) salts in neutral solutions. The efficiency of this reaction is comparable with the DNA cleavage by such systems as Cu(II)–phenanthroline and Cu(II)–ascorbic acid in efficiency, but, unlike them, it does not require the presence of an exogenous reducing agent or hydrogen peroxide. The Cu²⁺–arene system does not cleave DNA under anaerobic conditions. Catalase, sodium azide as well as bathocuproine, a specific chelator of Cu(I), completely inhibit the reaction. Our results suggest that Cu(I) ions, superoxide radical and singlet oxygen participate in this reaction. It was shown by EPR and spin traps that the reaction proceeds with the formation of alkoxyl radicals capable of inducing breaks in DNA molecules. An efficient cleavage of DNA in the Cu(II)–o-bromobenzoic acid system requires the generation of radicals under the conditions of formation of a specific copper–DNA–o-bromobenzoic acid complex, in which copper ions are likely to be coordinated with oxygen atoms of the DNA phosphate groups.     

Biomass relationship to growth and phosphate uptake ofPseudomonas fluorescens,Escherichia coli andAcinetobacter radioresistens in mixed liquor medium

The ability ofPseudomonas fluorescens, Escherichia coli andAcinetobacter radioresistenns to remove phosphate during growth was related to the initial biomass as well as to growth stages and bacterial species. Phosphate was removed by these bacteria under favourable conditions as well as under unfavourable conditions of growth. Experiments showed a relationship between a high initial cell density and phosphate uptake. More phosphate was released than removed when low initial cell densities (10²–10⁵ cells ml^–1) were used. At a high initial biomass concentration (10⁸ cells ml^–1), phosphate was removed during the lag phase and during logarthmic growth byP. fluorescens. Escherichia coli. at high initial biomass concentrations (10⁷ cells ml^–1), accumulated most of the phosphate during the first hour of the lag phase and/or during logarithmic growth and in some cases removed a small quantily of phosphate during the stationary growth phase.Acinetobacter radioresistens, at high initial cell densities (10⁶, 10⁷ cells ml^–1) removed most of phosphate during the first hour of the lag phase and some phosphate during the stationary growth phase.Pseudomonas fluorescens removed phosphate more thanA. radioresistens andE. coli with specific average ranges from 3.00–28.50 mg L^–1 compared to average ranges of 4.92–17.14 mg L^–1 forA. radioresistens and to average ranges of 0.50–8.50 mg L^–1 forE. coli.     

Evaluation of the effect of lipoic acid administered along with gentamicin in rats rendered bacteremic

Gentamicin is an aminoglycosidic antibiotic widely used in the treatment of many gram-negative bacterial infections. The present study was designed to investigate the extent of nephrotoxicity and the degree of protection afforded by lipoic acid under E. coli infected conditions and to note its effect on the antimicrobial activity of gentamicin. The study was carried out with adult male albino rats of Wistar strain. Group I animals served as controls. Group II animals were injected intraperitoneally for 2 successive days with 0.2 ml inoculum containing 10¹⁰ colony forming units of E. coli. Group III animals were injected E. coli as those in group II, in addition gentamicin 100 mg kg^–1 was administered intraperitoneally for 10 successive days. Group IV animals received intraperitoneal injections of E. coli as above plus gentamicin and also received lipoic acid (25 mg kg^–1) for 10 days by oral gavage. Rats subjected to E. coli administration showed a decline in the thiol content of the cell accompanied by high malondialdehyde levels along with lowered activities of catalase, superoxide dismutase and glutathione peroxidase with an added effect observed when gentamicin was administered along with it. The extent of nephrotoxicity induced by gentamicin was clearly evident with the decline in the activities of lactate dehydrogenase, alkaline phosphatase and N-acetyl--D-glucosaminidase in the rat renal tissues. A significant decrease was also observed in the activities of the transmembrane enzymes upon gentamicin administration. Treatment with lipoic acid decreased lipid peroxidation thereby maintaining the antioxidant status of the cell. The activities of the renal and transmembrane enzymes were also restored on lipoic acid treatment. The study has highlighted the beneficial effects of lipoic acid against experimental aminoglycoside toxicity in rats rendered bacteremic.     

Diffusion in immobilized-cell agar layers: influence of microbial burden and cell morphology on the diffusion coefficients ofl-malic acid and glucose

Summary The diffusivities ofl-malic acid and glucose in an agar membrane entrapping small amounts ofEscherichia coli orRhodospirillum rubrum whole cells were measured using time lag (TL) and steady state (SS) methods. Diffusivities were overestimated by the SS method. For concentrations of immobilizedR. rubrum cells ranging between 10⁴ and 10⁹ organisms cm^–3 agar (20 ng-2 mg dry weight cm^–3 agar), the diffusion coefficient ofl-malic acid, determined by both methods, was related to the logarithm of the membrane cell content by a decreasing linear relationship. The diffusion coefficient of glucose obtained by TL analysis was not significantly affected by the presence in the membrane of 3 ng-0.3 mg dry wt.E. coli cm^–3 agar. However, values arising from the SS method decreased linearly as a function of the amount of immobilized organisms. Membranes containingR. rubrum cells offered higher diffusional resistance tol-malic acid and glucose than those loaded with the same amount ofE. coli cells.     

Direct and indirect interactions for coexistence in a species-defined microcosm

Mechanisms for coexistence among micro-organisms were studied by using a species-defined microcosm, consisting of the bacterium Escherichia coli, the ciliate Tetrahymena thermophila and the alga Euglena gracilis. These organisms were chosen as representative of ecological functional groups i.e. decomposer, consumer and producer, respectively. Direct and indirect interactions among these organisms were evaluated by comparisons of their population dynamics in culture with different combinations of the three species. There was an E. coli cell density dependent predator–prey interaction between T. thermophila and E. coli which was only established when there were more than 10⁶ cells ml^–1 of E. coli. Indirect interactions were evaluated from the cultivation of each organism in media containing metabolites of the others. Metabolites from each population strongly accelerated the growth of their own populations and those of the others except for the self-toxicity effect of E. coli metabolites. These observations suggested that not only the cell–cell contact of direct interactions, but also metabolite-mediated indirect interactions supported the maintenance of the populations of each micro-organism and their coexistence. In natural ecosystems, there are many interactions and it is difficult to evaluate all those regulating community dynamics. The gnotobiotic microcosm used in this study was shown to be suitable for examining the specific, species–species microbial interactions.     

Thermo-osmoregulation of Heat-Labile Enterotoxin Expression by <Emphasis Type="Italic">Escherichia coli</Emphasis>

Abstract:Enterotoxigenic Escherichia coli causes diarrhea by producing several virulence factors including heat-labile enterotoxin (LT). LT is maximally expressed at 37°C. The histone-like nucleoid structuring protein (H-NS) appears to inhibit LT expression by binding to a downstream regulatory element (DRE) at low temperatures. An hns⁺ E. coli strain, X7026, carrying an LT–beta-galactosidase translational fusion plasmid (pLT-lac) was shown to be responsive to varying amounts of sodium chloride (NaCl) as well as sucrose or lithium chloride. Maximal responsiveness to the various osmolytes was obtained with cells grown at 37°C under microaerophilic conditions. Temperature-osmotic upshift experiments demonstrate LT expression is thermo-osmoregulated. pLT-lac was tested in an hns strain or its congenic hns⁺ strain for its response to NaCl. LT expression is elevated in the hns strain regardless of NaCl concentration and retains its osmoresponsiveness. The response of the DRE deletion plasmid (pLT-lacNC) to NaCl is similar to that of the undeleted plasmid.     

Selenium enhances the antimutagenic activity of probiotic bacterium Enterococcus faecium M-74

The antibacterial activity of the probiotic bacterium Enterococcus faecium M-74 was assessed on De Man–Rogosa–Sharpe (MRS), Todd–Hewitt (T–H), M17 (M-17) and brain heart infusion (BHI) media with sodium selenite pentahydrate (+Se) and without sodium selenite pentahydrate (–Se) under aerobic or anaerobic conditions against nine bacterial pathogens. The highest antibacterial activity was found to be in the MRS medium under anaerobic conditions. There were no differences in the antibacterial activity between MRS(+Se) and MRS(–Se) media. The antimutagenic activity of MRS(+Se) and MRS(–Se) extracts after culture with E. faecium M-74 as well as of live and killed cells of E. faecium M-74 grown in the presence or absence of Se against the genotoxicity of ofloxacin (OFL) and acridine orange (AO) was determined in the Euglena gracilis assay. The MRS(+Se) extracts showed a significantly higher activity in reducing the genotoxicity of OFL and AO than MRS(–Se) extracts. The live cells of the probiotic strain M-74 exhibited higher antimutagenic activity than the killed bacterial cells, but differed depending on the mutagen used. However, the live bacterial cells grown in the presence of Se showed significantly higher antimutagenic activity. These results suggest a potential benefit for the future development of new Se-enriched probiotics exhibiting higher antimutagenic properties.     

The effect of growth rate and other growth conditions on the lipid composition of Escherichia coli

Escherichia coli was grown as a continuous culture at various defined conditions of temperature, pH, aeration rate and dilution rate. The lipids were extracted from disrupted cells and the relative fatty acid content of the individual and total phospholipids was determined. The lipid composition of E. coli was shown to change with the fermentation conditions. Interestingly, E. coli adapted to high growth rates and to low oxygen tension by changing the lipid composition of the membrane in exactly the same way, thus indicating a common effect.     

Plasmid mediated metal and antibiotic resistance in marinePseudomonas

Pseudomonas sp isolated from the Bay of Bengal (Madras coast) contained a single large plasmid (pMR1) of 146 kb. Plasmid curing was not successful with mitomycin C, sodium dodecyl sulfate, acridine orange, nalidixic acid or heat. Transfer of mercury resistance from marinePseudomonas toEscherichia coli occurred during mixed culture incubation in liquid broth at 10^–4 to 10^–5 ml^–1. However, transconjugants lacked the plasmid pMR1 and lost their ability to resist mercury. Transformation of pMR1 intoE. coli competent cells was successful; however, the efficiency of transformation (1.49×10² Hg^r transformants g^–1 pMR1 DNA) was low.E. coli transformants containing the plasmid pMR1 conferred inducible resistance to mercury, arsenic and cadmium compounds similar to the parental strain, but with increased expression. The mercury resistant transformants exhibited mercury volatilization activity. A correlation existed between metal and antibiotic resistance in the plasmid pMR1.     

Dehydroascorbate reduction

Dehydroascorbic acid is generated in plants and animal cells by oxidation of ascorbic acid. The reaction is believed to occur by the one-electron oxidation of ascorbic acid to semidehydroascorbate radical followed by disproportionation to dehydroascorbic acid and ascorbic acid. Semidehydroascorbic acid may recycle to ascorbic acid catalyzed by membrane-bound NADH-semidehydroscorbate reductase. However, disproportionation of the free radical occurs at a rapid rate, 10⁵ M^–1 s^–1, accounting for measurable cellular levels of dehydroascorbate. Dehydroascorbate reductase, studied earlier and more extensively in plants, is now recognized as the intrinsic activity of thioltransferases (glutaredoxins) and protein disulfide isomerase in animal cells. These enzymes catalyze the glutathione-dependent two-electron regeneration of ascorbic acid. The importance of the latter route of ascorbic acid renewal was seen in studies of GSH-deficient rodents (Meister, A. (1992)Biochem. Pharmacol. 44 1905–1915). GSH deficiency in newborn animals resulted in decreased tissue ascorbic acid and increased dehydroascorbate-to-ascorbate ratios. Administration of ascorbic acid daily to GSH-deficient animals decreased animal mortality and cell damage from oxygen stress. A cellular role is proposed for dehydroascorbate in the oxidation of nascent protein dithiols to disulfides catalyzed in the endoplasmic reticulum compartment by protein disulfide isomerase.     

Metabolism of d(+)-carnitine by Escherichia coli

Summary Escherichia coli 044 K74 grown under anaerobic conditions in the presence of l(–)-carnitine is able to convert d(+)-carnitine into the l(–)-enantiomer. This activity is repressed by electron acceptors such as oxygen and nitrate as well as by glucose. d(+)-Carnitine shows no effect on the induction or repression of the corresponding enzyme or enzyme system. Resting cells of E. coli 044 K74 were used for the formation of l(–)-carnitine from d(+)-carnitine. The maximum obtained yield was 50%. -Butyrobetaine was formed as a by-product. Offprint requests to: H. Jung     

Brachionus calyciflorus Pallas as agent for the removal of E. coli in sewage ponds

Brachionus calyciflorus (Pallas) is a common brachionid in sewage oxidation ponds. The uptake and assimilation of E. coli was optimal at concentrations of 2.7–6.9 × 10⁸ cells ml^–1 while assimilation coefficient per body weight of B. calyciflorus was found to be 10% · Ind.^–1 d^–1. More than two eggs per individual were produced during 24 hours when brachionids were fed with a mixutre of E. coli (10⁹ cells · ml^–1) and Chlorella spp. (10⁶ cells · ml^–1). The nutritional value of the mixture of E. coli and Chlorella spp. was found to be higher than that of bacteria alone.     

Anaerobic Transfer of Antibiotic Resistance from Pseudomonas aeruginosa

Pseudomonas aeruginosa, an opportunistic pathogen that often initiates infections from a reservoir in the intestinal tract, may donate or acquire antibiotic resistance in an anaerobic environment. Only by including nitrate and nitrite in media could antibiotic-resistant and -sensitive strains of P. aeruginosa be cultured in a glove box isolator. These anaerobically grown cells remained sensitive to lytic phage isolated from sewage. After incubation with a phage lysate derived from P. aeruginosa 1822, anaerobic transfer of antibiotic resistance to recipients P. aeruginosa PS8EtBr and PS8EtBrR occurred at frequencies of 6.2 × 10⁻⁹ and 5.0 × 10⁻⁸ cells per plaque-forming unit, respectively. In experiments performed outside the isolator, transfer frequencies to PS8EtBr and PS8EtBrR were higher, 1.3 × 10⁻⁷ and 6.5 × 10⁻⁸ cells per plaque-forming unit, respectively. When P. aeruginosa 1822 was incubated aerobically with Escherichia coli B in medium containing nitrate and nitrite, the maximum concentration of carbenicillin-resistant E. coli B reached 25% of the total E. coli B population. This percentage declined to 0.01% of the total E. coli B population when anaerobically grown P. aeruginosa 1822 and E. coli B were combined and incubated in the glove box isolator. The highest concentration of the recipient population converted to antibiotic resistance occurred after 24 h of aerobic incubation, when an initially high donor/recipient ratio (>15) of cells was mixed. These data indicate that transfer of antibiotic resistance either by transduction between Pseudomonas spp. or by conjugation between Pseudomonas sp. and E. coli occurs under strict anaerobic conditions, although at lower frequencies than under aerobic conditions.     

Enhanced protection of pathogenic Escherichia coli ingested by a soil nematode Caenorhabditis elegans against sanitizer treatments

We employed Caenorhabditis elegans as a model to study the effectiveness of sanitizers in killing pathogenic Escherichia coli strains ingested by free-living nematodes. Adult worms that had fed on six pathogenic E. coli strains (highly persistent in the nematode intestine) were treated with three chemical solutions. In planktonic cells, none of the H₂O₂ and acetic acid treatments influenced the survival of the pathogenic E. coli strains, whereas sodium hypochlorite critically decreased the viability of the strains. Importantly, the survival of the E. coli strains was dramatically increased by persistence in the C. elegans gut under 0.1% sodium hypochlorite, and several strains could survive at a concentration of 0.5%. In addition, all pathogenic E. coli strains in the C. elegans gut survived on the lettuce for 5?days even though they were washed with 0.1% sodium hypochlorite. Taken together, our results indicate that pathogenic E. coli ingested by C. elegans may be protected against washing treatment with commercial sanitizers on raw food materials.     

Fimbriae and lipopolysaccharides are necessary for co-aggregation between Lactobacilli and Escherichia coli

Cells of Lactobacilli co-aggregated with Escherichia coli K-12 cells to form co-aggregates under mixed-culture conditions at 37?°C for 24?h. Co-aggregation was inhibited by sodium dodecyl sulfate but not by protease. E. coli deletion mutants of fimbriae formation and lipopolysaccharide (LPS) formation did not co-aggregate with Lactobacilli. These results showed that fimbriae and LPS are necessary for co-aggregation between Lactobacilli and E. coli.     

Adenosine deamination increases the survival under acidic conditions in Escherichia coli

Aims: Resistance to acidic stress contributes to bacterial persistence in the host and is thought to promote their passage through the human gastric barrier. The aim of this study was to examine whether nucleosides have a role in the survival under acidic conditions in Escherichia coli. Methods and Results: We found that adenosine has a function to survive against extremely acidic stress. The deletion of add encoding adenosine deaminase that converts adenosine into inosine and NH₃ attenuated the survival in the presence of adenosine. The addition of adenosine increased intracellular pH of E. coli cells in pH 2·5 medium. Addition of inosine or adenine did not increase the resistance to acidic conditions. Conclusions: Our present results imply that adenosine was used to survive under extremely acidic conditions via the production of NH₃. Significance and Impact of the Study: It has been proposed that amino acid decarboxylation is the major system for the resistance of E. coli to acidic stress. In this study, the adenosine deamination was shown to induce the survival under acidic conditions, demonstrating that bacteria have alternative strategies to survive under acidic conditions besides amino acid decarboxylation.