Effect of glucose on the induced synthesis of bacterial respiratory nitrate reductase and tetrathionate reductase

The activities of respiratory nitrate reductase and tetrathionate reductase inCitrobacter growing anaerobically in the presence of nitrate or tetrathionate were determined. Both activities were three times higher in cells growing on lactose than in glucose-growing cells. Also, the ability of washed, non-growing cells to form both reductases was greatly diminished when glucose served as the energy source during previous growth. The effect was not specific for glucose and was not due to lack of amino acids.     

Regulation of reductase formation in Proteus mirabilis

Summary Prteus mirabilis can form four reductases after anaerobic growth: nitrate reductase A, chlorate reductase C, thiosulfate reductase and tetrathionate reductase. The last three enzymes are formed constitutively. Nitrate reductase is formed only after growth in the presence of nitrate, which causes repression of the formation of thiosulfate reductase, chlorate reductase C, tetrathionate reductase and hydrogenase. Formic dehydrogenase assayed with methylene blue as hydrogen acceptor is formed under all conditions.Two groups of chlorate resistant mutants were obtained. One group does not form the reductases and formic dehydrogenase. The second group does not form nitrate reductase, chlorate reductase and hydrogenase, but forms formic dehydrogenase and small amounts of formic hydrogenlyase after growth without hydrogen acceptor or after growth in the presence of thiosulfate or tetrathionate. Nitrate prevents the formation of formic dehydrogenase, thiosulfate reductase and tetrathionate reductase in this group of mutants. Only after growth with thiosulfate or tetrathionate the reductases for these compounds are formed. Anaerobic growth of the wild type in complex medium without a fermentable carbon source is strongly stimulated by the presence of nitrate. Tetrathionate and thiosulfate have no effect at all or only a small effect. The results show that in the presence of tetrathionate or thiosulfate the bacterial metabolism is fully anaerobic, as these cells also contain formic hydrogenlyase.     

Tetrathionate reductase of Salmonella thyphimurium: a molybdenum containing enzyme

Use of radioactive molybdenum demonstrates that the tetrathionate reductase of Salmonella typhimurium is a molydenum containing enzyme. It is proposed that this enzyme shares with other molybdo-proteins, such as nitrate reductase, a common molybdenum containing cofactor the defect of which leads to the loss of the tetrathionate reductase and nitrate reductase activities.     

Regulation of reductase formation in Proteus mirabilis

Summary The levels of several redox enzymes in a chlorate-resistant mutant of Proteus mirabilis, which is partially affected in the formation of formate hydrogenlyase, thiosulfate reductase and tetrathionate reductase, were compared with those of the wild type. The composition of the electron transport system of both strains was almost the same in cells grown aerobically, but very different in cells grown anaerobically. In the mutant, the cytochrome content increased twofold, whereas the level of the anaerobic enzymes is strongly diminished. The anaerobic formation of electron transport components in the mutant was, in contrast to that of the wild type, not influenced significantly by azide. During anaerobic growth with nitrate low levels of a functional nitrate reductase system were formed in the mutant. Under these conditions the formation of formate dehydrogenase, formate hydrogenlyase, formate oxidase, thiosulfate reductase, tetrathionate reductase, cytochrome b_563,5 and partly that of cytochrome a₂, was repressed. The repressive effect of nitrate, however, was completely abolished by azide. Therefore, it seems likely that a functional nitrate reductase system, rather than nitrate, controls the formation of the enzymes repressible by nitrate.     

Reduction of inorganic sulphur compounds by facultatively aerobic bacteria

Summary Amongst the family of the Enterobacteriaceae the ability to reduce tetrathionate to thiosulfate and thiosulfate to sulfite and sulfide occurs in the genera Proteus, Citrobacter and Salmonella. These reductions are coupled to a respiratory chain which functions under anaerobic conditions. Only during transport of electrons to tetrathionate oxidative phosphorylation has been demonstrated. Isolation and purification of the cytoplasmic membrane bound tetrathionate and thiosulfate reductase fromProteus mirabilis makes clear that this bacterium forms only one enzyme for both reductions. This enzyme has a molecular weight of 133,000 daltons and can be divided into two subunits with molecular weights of 43,000 and 90,000 daltons by treatment with sodium dodecyl sulfate and 2-mercaptoethanol. The reduction of tetrathionate is activated by its primary product thiosulfate. Nitrate or oxygen represses and inactivates the tetrathionate and thiosulfate reductase. Nevertheless the smaller subunit of this enzyme appears to be formed and assembled into the cytoplasmic membranes after anaerobic growth in the presence of nitrate. Paper read at the Symposium on the Sulphur Cycle, Wageningen, May 1974.     

Influence of hydrogen acceptors on growth and energy production ofProteus mirabilis

The generation time ofP. mirabilis in defined and in complex medium is shorter in the presence of hydrogen acceptors than in their absence. In the presence of hydrogen acceptors the molar growth yield for glucose and the acetate production are strongly increased. From the molar growth yield and the acetate production Y_ATP in defined medium was calculated as 5.5 g/mole, whereas in complex medium a value of 12.6 g/mole was obtained. The molar growth yield, the acetate production, the amount of hydrogen acceptor reduced and Y_ATP were used to calculate P/2e⁻ratios for phosphorylation coupled to electron transfer to oxygen, nitrate and tetrathionate as respectively 2.80; 1.48 and 1.23 in defined medium. Under anaerobic conditions in the presence of nitrate or tetrathionate as hydrogen acceptor in complex medium a bend in the growth curve is observed. In the period of rapid growth the P/2e⁻ratio for nitrate reduction is of the same magnitude as that in defined medium, however much lower P/2e⁻ratios are found during the subsequent period of slow growth. The P/2e⁻ratios for tetrathionate reduction in complex medium for both growth periods are lower than those in defined medium. Most probably these results indicate that during this period growth and energy production are uncoupled. Under aerobic conditions in complex medium a constant Y_O value of 32.2 g/atom O is found during a short period of the growth curve. Afterwards when the cell density increases a steady decrease of Y_O is observed.     

Oxidation kinetics and chemostat growth kinetics of Thiobacillus ferrooxidans on tetrathionate and thiosulfate.

Growth of Thiobacillus ferrooxidans in batch culture on 10 mM potassium tetrathionate was optimal at pH 2.5 (specific growth rate, 0.092 h-1). Oxygen electrode studies on resting cell suspensions showed that the apparent Km for tetrathionate oxidation (0.13 to 8.33 mM) was pH dependent, suggesting higher substrate affinity at higher pH. Conversely, oxidation rates were greatest at low pH. High substrate concentrations (7.7 to 77 mM) did not affect maximum oxidation rates at pH 3.0, but produced substrate inhibition at other pH values. Tetrathionate-grown cell suspensions also oxidized thiosulfate at pH 2.0 to 4.0. Apparent Km values (1.2 to 25 mM) were of the same order as for tetrathionate, but kinetics were complex. Continuous culture on growth-limiting tetrathionate at pH 2.5, followed by continuous culture on growth-limiting thiosulfate at pH 2.5, indicated true growth yield values (grams [dry weight] per gram-molecule of substrate) of 12.2 and 7.5, and maintenance coefficient values (millimoles of substrate per gram [dry weight) of organisms per hour) of 1.01 and 0.97 for tetrathionate and thiosulfate, respectively. Yield was increased on both media at low dilution rates by increase in CO2 supply. The apparent maintenance coefficient was lowered without affecting YG, suggesting better energy coupling in CO2-rich environments. Prolonged continuous cultivation on tetrathionate or thiosulfate did not affect the ability of the organism to grow subsequently in ferrous iron medium.     

Control of nitrate concentration in fermentations of Corynebacterium glutamicum

A nitrate control system has been devised for the maintenance of stable nitrate concentrations throughout fed-batch fermentations of Corynebacterium glutamicum. The feedback control system was based on the use of a nitrate-ion-selective electrode to directly monitor the nitrate levels in the fermentor and an automatic controller to activate a nitrate feed pump. The electrode which was used for controlling the nitrate level was stable through-out the fermentation period. The apparent maximum specific growth rate, biomass production, protein production, biomass yields on glucose and nitrate, and amino acid production were all optimal at approximately 50mM nitrate.     

Linkage of formate hydrogenlyase with anaerobic respiration in Proteus mirabilis

The linkage between the enzyme system catalysing formate hydrogenlyase and reductases involved in anaerobic respiration in intact cells of anaerobically grown Proteus mirabilis was studied. Reduction of nitrate and fumarate by molecular hydrogen or formate was possible under all growth conditions; reduction of tetrathionate and thiosulphate occurred only in cells harvested at late growth phase from a pH-regulated batch culture and not in cells harvested at early growth phase or in cells grown in pH-auxostat culture. Under all conditions, cells possessed the enzyme tetrathionate reductase. We conclude that linkage between tetrathionate reductase (catalysing also reduction of thiosulphate) and the formate hydrogenlyase chain is dependent on growth conditions. During reduction of high-potential oxidants such as fumarate, tetrathionate (when possible) or the artificial electron acceptor methylene blue by formate, there was no simultaneous H₂ evolution due to the formate hydrogenlyase reaction. H₂ production started only after complete reduction of methylene blue or fumarate, in the case of methylene blue after a lag phase without gas production. In preparations with a low fumarate reduction activity this was accompanied by an acceleration in CO₂ production. During reduction of thiosulphate (a low-potential oxidant) or of tetrathionate in the presence of benzyl viologen (a low-potential mediator) by formate, H₂ was evolved simultaneously. From this we conclude that formate hydrogenlyase is regulated by a factor that responds to the redox state of any electron acceptor couple present such that lyase activity is blocked when the acceptor couple is oxidised to too great an extent.     

Isolation and physiological characterisation of Thiobacillus aquaesulis sp. nov., a novel facultatively autotrophic moderate thermophile

A moderately thermophilic, facultatively chemolithoautotrophic thiobacillus isolated from a thermal sulphur spring is described. It differs from all other species currently known to be in culture. It grows lithoautotrophically on thiosulphate, trithionate or tetrathionate, which are oxidized to sulphate. Batch cultures on thiosulphate do not produce tetrathionate, but do precipitate elemental sulphur during growth. In autotrophic chemostat cultures the organism produces yields on thiosulphate, trithionate and tetrathionate that are among the highest observed for a Thiobacillus. Autotrophic cultures contain ribulose bisphosphate carboxylase. Heterotrophic growth has been observed only on complex media such as yeast extract and nutrient broth. It is capable of autotrophic growth and denitrification under anaerobic conditions with thiosulphate and nitrate. It grows between 30 to 55° C, and pH 7 to 9, with best growth at about 43°C and pH 7.6. It contains ubiquinone Q-8, and its DNA contains 65.7 mol% G+C. The organism is formally described and named as Thiobacillus aquaesulis.Now the Department of Biological Sciences     

Factors influencing the rate of electron transport in different respiratory pathways of bacteria

The rate of electron transfer by a respiratory pathway as dependent on pH, temperature, concentration of cyanide and concentration of azide was followed in washed non-growing cells ofCitrobacter. Three respiratory pathways leading to three terminal electron acceptors, i.e. oxygen, tetrathionate and nitrate, were investigated. It was found that these pathways mutually differ in their response to pH, temperature, cyanide and azide and conditions favouring inhibition or stimulation of one electron transport pathway relatively to the other two pathways were established.     

Isolation from Salmonella typhimurium LT2 of mutants lacking specifically nitrate reductase activity and mapping of the chl-C gene

Summary Addition of tetrathionate and nitrate to EMB medium allows the isolation from Salmonella typhimurium LT2 of mutants lacking specifically nitrate reductase A activity. Genetic localization of such chl-C mutations leads to the conclusion that the affected gene is close to tdk but outside the trp-tdk segment and that chl-C is an early marker in Hfr B2.     

Tetrathionate stimulated growth of Campylobacter jejuni identifies a new type of bi‐functional tetrathionate reductase (TsdA) that is widely distributed in bacteria

Tetrathionate (S₄O₆^2?) is used by some bacteria as an electron acceptor and can be produced in the vertebrate intestinal mucosa from the oxidation of thiosulphate (S₂O₃^2?) by reactive oxygen species during inflammation. Surprisingly, growth of the microaerophilic mucosal pathogen Campylobacter jejuni under oxygen‐limited conditions was stimulated by tetrathionate, although it does not possess any known type of tetrathionate reductase. Here, we identify a dihaem cytochrome c (C8j_0815; TsdA) as the enzyme responsible. Kinetic studies with purified recombinant C. jejuni TsdA showed it to be a bifunctional tetrathionate reductase/thiosulphate dehydrogenase with a high affinity for tetrathionate. A tsdA null mutant still slowly reduced, but could not grow on, tetrathionate under oxygen limitation, lacked thiosulphate‐dependent respiration and failed to convert thiosulphate to tetrathionate microaerobically. A TsdA paralogue (C8j_0040), lacking the unusual His–Cys haem ligation of TsdA, had low thiosulphate dehydrogenase and tetrathionate reductase activities. Our data highlight a hitherto unrecognized capacity of C. jejuni to use tetrathionate and thiosulphate in its energy metabolism, which may promote growth in the host. Moreover, as TsdA represents a new class of tetrathionate reductase that is widely distributed among bacteria, we predict that energy conserving tetrathionate respiration is far more common than currently appreciated.     

Kinetics and energetics of reduced sulfur oxidation by chemostat cultures of Thiobacillus ferrooxidans

Thiobacillus ferrooxidans was grown in chemostat cultures with thiosulfate and tetrathionate as the limiting substrates. The yields at steady state on both substrates at different dilution rates were calculated. In a few experiments the air supply was supplemented with 2% CO₂ (v/v). This resulted in a slightly increased yield.Cells from the chemostat cultures were used to study the kinetics of thiosulfate, tetrathionate, sulfite and sulfide oxidation. With all substrates mentioned the Ks values were in the micromolar range. The values for thiosulfate and tetrathionate were 2 orders of magnitude lower that those published previously.     

Nitrate ion-selective electrode in microbial media

A nitrate ion-selective electrode has been used to follow the kinetics of the reduction of nitrate by a bacillus isolated from the rumen of a sheep. The electrode system and the microbial culture were found to be quite compatible, although the formation of nitrite limits the utility and precision of the measurement. The formation of nitrite was followed simultaneously by a colorimetric method. Nitrate was converted quantitatively to nitrite. The rate of the reaction was found to increase to a plateau value, then drop abruptly when the nitrate was exhausted.     

Dissimilatory nitrate reduction by Pseudomonas alcaliphila with an electrode as the sole electron donor

Denitrification and dissimilatory nitrate reduction to ammonium (DNRA) were considered two alternative pathways of dissimilatory nitrate reduction. In this study, we firstly reported that both denitrification and DNRA occurred in Pseudomonas alcaliphila strain MBR with an electrode as the sole electron donor in a double chamber bio‐electrochemical system (BES). The initial concentration of nitrate appeared as a factor determining the type of nitrate reduction with electrode as the sole electron donor at the same potential (?500 mV). As the initial concentration of nitrate increased, the fraction of nitrate reduced through denitrification also increased. While nitrite (1.38 ± 0.04 mM) was used as electron acceptor instead of nitrate, the electrons recovery via DNRA and denitrification were 43.06 ± 1.02% and 50.51 ± 1.37%, respectively. The electrochemical activities and surface topography of the working electrode catalyzed by strain MBR were evaluated by cyclic voltammetry and scanning electron microscopy. The results suggested that cells of strain MBR were adhered to the electrode, playing the role of electron transfer media for nitrate and nitrite reduction. Thus, for the first time, the results that DNRA and denitrification occurred simultaneously were confirmed by powering the strain with electricity. The study further expanded the range of metabolic reactions and had potential value for the recognization of dissimilatory nitrate reduction in various ecosystems. Biotechnol. Bioeng. 2012; 109: 2904–2910. © 2012 Wiley Periodicals, Inc.     

The correlation between the protein composition of cytoplasmic membranes and the formation of nitrate reductase A,chlorate reductase C and tetrathionate reductase in Proteus mirabilis wild type and some chlorate resistant mutants

Three genotypically different chlorate resistant mutants, chl I, chl II and chl III, appeared to lack completely nitrate reductase A, chlorate reductase C and tetrathionate reductase activity. Fumarate reductase is only partially affected in chl I and chl III and unaffected in chl II. Formate dehydrogenase is only partially diminished in chl II, hydrogenase is diminished in chl I and chl II and completely absent in chl III.Subunits of nitrate reductase A, chlorate reductase C and tetrathionate reductase have been identified in protein profiles of purified cytoplasmic membranes from the wild type and the three mutant strains, grown under various conditions. Only the presence and absence of the largest subunits of these enzymes appeared to be correlated with their repression and derepression in the wild type membranes. On the cytoplasmic membranes of the chl I and chl III mutants these subunits lack for the greater part. In the chl II mutant, however, these subunits are inserted in the membrane all together after anaerobic growth with or without nitrate.A model for the repression/derepression mechanism for the reductases has been proposed. It includes repression by cytochrome b components, whereas the redox-state of the nitrate reductase A molecule itself is also involved in its derepression under anaerobic conditions.     

Tetrathionate reductase as a diagnostic trait in identifying Pseudomonas aeruginosa

The tetrathionate reductase test may be used for the identification of P. aeruginosa. The most reliable results have been obtained with the use of a medium containing sodium tetrathionate for this purpose, and replacing bromthymol blue used as an indicator for phenol red excludes the possibility of false negative reactions.     

Studies on Biochemistry of the Thiobacilli

In the oxidation of thiosulfate at pH 4.5 tetrathionate was formed as an intermediate, and the thiosulfate-oxidizing enzyme was active in acidic pH range in contrast to the enzyme of T. thioparus and Thiobacillus X.

Phosphate did not seem to affect the oxidation of thiosulfate but rather affect the conversion of tetrathionate. In the absence of phosphate, tetrathionate, which was produced from thiosulfate oxidation, seemed to accumulate without undergoing further conversion.

Quantitative oxidation of tetrathionate to sulfate was achieved with freshly harvested cells of T. thiooxidans; pH optimum for the oxidation of tetrathionate by the washed cells was 2~3, and the activity fell markedly at pH above 3.5.

Tetrathionate might be enzymatically dismuted to pentathionate and trithionate under anaerobic conditions with crude extracts of T. thiooxidans; pH optimum for the reaction was about 2.7 and the activity fell strikingly at pH 4.7. The formed trithionate might be further hydrolyzed to thiosulfate and sulfate.     

Reduced sulfur compound oxidation by Thiobacillus caldus.

The oxidation of reduced inorganic sulfur compounds was studied by using resting cells of the moderate thermophile Thiobacillus caldus strain KU. The oxygen consumption rate and total oxygen consumed were determined for the reduced sulfur compounds thiosulfate, tetrathionate, sulfur, sulfide, and sulfite in the absence and in the presence of inhibitors and uncouplers. The uncouplers 2,4-dinitrophenol and carbonyl cyanide m-chlorophenyl-hydrazone had no affect on the oxidation of thiosulfate, suggesting that thiosulfate is metabolized periplasmically. In contrast, the uncouplers completely inhibited the oxidation of tetrathionate, sulfide, sulfur, and sulfite, indicating that these compounds are metabolized in the cytoplasm of T. caldus KU. N-Ethylmaleimide inhibited the oxidation of tetrathionate and thiosulfate at the stage of elemental sulfur, while 2-heptyl-4-hydroxyquinoline-N-oxide stopped the oxidation of thiosulfate, tetrathionate, and elemental sulfur at the stage of sulfite. The following intermediates in the oxidation of the sulfur compounds were found by using uncouplers and inhibitors: thiosulfate was oxidized to tetrathionate, elemental sulfur was formed during the oxidation of tetrathionate and sulfide, and sulfite was found as an intermediate of tetrathionate and sulfur metabolism. On the basis of these data we propose a model for the metabolism of the reduced inorganic sulfur compounds by T. caldus KU.