Location of anaerobic respiratory enzyme trimethylamine N-oxide reductase in the cytoplasmic membrane ofEscherichia coli strain K10

Trimethylamine N-oxide (TMAO) reductase, which is anaerobically induced by TMAO, is a terminal enzyme in anaerobic electron transport inEscherichia coli. When the organism was anaerobically grown with TMAO, a marked increase in the specific activity of TMAO reductase was observed mainly in a cell membrane fraction and stopped after exhausting TMAO. On the other hand, activity was moderately increased in a soluble fraction of the cell even after exhaustion of TMAO. Immunoblot analysis with an antiserum against the TMAO reductase purified from the soluble fractions showed that the cells growing with TMAO contained only a membrane-bound enzyme, which has a molecular mass of 94 kDa, while a soluble enzyme with 92 kDa appeared in the stationary growth phase lacking TMAO. Experiments with right-side-out and inside-out vesicles of cytoplasmic membrane indicated that the membrane-bound enzyme faces the cytoplasm. The soluble enzyme was mainly found in the cytoplasm of the cell, but also at a negligible amount in the periplasm. The membrane-bound form of TMAO reductase functioning in anaerobic electron transport seems to be cleaved and released into the cytoplasm as soluble enzyme after exhaustion of TMAO.     

Anaerobic respiratory growth of Vibrio harveyi, Vibrio fischeri and Photobacterium leiognathi with trimethylamine N-oxide, nitrate and fumarate: ecological implications

Two symbiotic species, Photobacterium leiognathi and Vibrio fischeri, and one non-symbiotic species, Vibrio harveyi, of the Vibrionaceae were tested for their ability to grow by anaerobic respiration on various electron acceptors, including trimethylamine N-oxide (TMAO) and dimethylsulphoxide (DMSO), compounds common in the marine environment. Each species was able to grow anaerobically with TMAO, nitrate or fumarate, but not with DMSO, as an electron acceptor. Cell growth under microaerophilic growth conditions resulted in elevated levels of TMAO reductase, nitrate reductase and fumarate reductase activity in each strain, whereas growth in the presence of the respective substrate for each enzyme further elevated enzyme activity. TMAO reductase specific activity was the highest of all the reductases. Interestingly, the bacteria-colonized light organs from the two squids, Euprymna scolopes and Euprymna morsei, and the light organ of the ponyfish, Leiognathus equus, also had high levels of TMAO reductase enzyme activity, in contrast to non-symbiotic tissues. The ability of these bacterial symbionts to support cell growth by respiration with TMAO may conceivably eliminate the competition for oxygen needed for both bioluminescence and metabolism.     

Differentiation of the multiple S- and N-oxide-reducing activities ofEscherichia coli

InEscherichia coli, several terminal reductases catalyze the reduction of S- and N-oxide compounds. We have used mutants missing either the constitutive dimethylsulfoxide (DMSO) reductase,dmsABC, and/or the inducible trimethylamine N-oxide (TMAO) reductase,torA, to define the roles of each reductase. These studies indicated that the constitutive DMSO reductase can sustain growth on DMSO, TMAO, methionine sulfoxide (MetSO), and other N-oxide compounds. Only one inducible TMAO reductase is expressed inE. coli, and this enzyme sustains growth on TMAO but not DMSO or MetSO. Characterization of atorA ^–, dms^–double mutant revealed that adenosine N-oxide (ANO) reductase is specifically required for anaerobic respiration on ANO in this mutant.     

The effect of oxygen on denitrification during steady-state growth of Paracoccus halodenitrificans

Dimethylsulphoxide (DMSO) and trimethylamine oxide (TMAO) sustained anaerobic growth of Proteus vulgaris with the non-fermentable substrate lactate. Cytoplasmic membrane vesicles energized by electron transfer from formate to DMSO displayed anaerobic uptake of serine, which was hindered by metabolic inhibitors known to destroy the proton motive force. This showed that DMSO reduction was coupled with a chemiosmotic mechanism of energy conversion; similar data for TMAO respiration have been presented previously. All biochemical tests applied indicated that the oxides were reduced by the same reductase system. The DMSO and TMAO reductase activities showed the same mobility on ion-exchange chromatography, and polyacrylamide disc gel electrophoresis (pH 8.9), gradient gel electrophoresis, and gel isoelectric focusing; mol. wt. and pI determined were 95,000 and 4.6, respectively. DMSO inhibited reduction of [¹⁴C]TMAO in vesicles. The reductase was inducible to a certain extent; both oxides being equally efficient as inducers. TMAO was reduced at a higher rate than DMSO, explaining faster growth of cells and increased uptake of serine in vesicles with TMAO as electron acceptor. Comparative studies with Escherichia coli also gave evidence for common TMAO and DMSO reductase systems.Abbreviations TMAO trimethylamine oxide - DMSO dimethylsulphoxide     

Nucleic acid spot hybridization for detection of Chlamydia trachomatis

Abstract The TMAO reductase activity of Escherichia coli grown anaerobically in the presence or absence of TMAO was analysed on linear sucrose gradients and on non-denaturing polyacrylamide gels. The results, together with those obtained by analysis of some other properties of TMAO reductase, showed that there are significant differences between the enzyme synthesized in the absence of TMAO ("constitutive" enzyme) and that synthesized in its presence ("inducible" enzyme).
A similar study of a tor mutant specifically altered in the structural gene for TMAO reductase, showed that the enzymes synthesized under the 2 growth conditions are probably 2 distinct enzymes encoded by different genes.     

Chlorate and nitrate reduction in the phototrophic bacteriaRhodobacter capsulatus andRhodobacter sphaeroides

Chlorate or trimethylamine-N-oxide (TMAO) added to phototrophic cultures ofRhodobacter sphaeroides DSM 158 increased both the growth rate and the growth yield although this stimulation was not observed in the presence of tungstate. This strain, exhibited basal activities of nitrate, chlorate, and TMAO reductases independently of the presence of these substrates in the culture medium, and nitrate reductase (NR) activity was competitively inhibited by chlorate. Phototrophic growth ofRhodobacter capsulatus B10, a strain devoid of NR activity, was inhibited only by 100 mM chlorate. However, growth of the nitrate-assimilatingR. capsulatus strains E1F1 and AD2 was sensitive to 10mm chlorate, and their NR activities were not inhibited by chlorate. Both NR and chlorate reductase (CR) activities of strain E1F1 were induced in the presence of nitrate or chlorate respectively, whereas strain AD2 showed basal levels of these activities in the absence of the substrates. A basal TMAO reductase (TR) activity was also observed when these strains ofR. capsulatus were cultured in the absence of this electron acceptor. These results suggest that chlorate and TMAO can be used as ancillary oxidants byRhodobacter strains and that a single enzyme could be responsible for nitrate and chlorate reduction inR. sphaeroides DSM 158, whereas these reactions are catalyzed by two different enzymes inR. capsulatus E1F1 and AD2.     

Effects of ISSo2 insertions in structural and regulatory genes of the trimethylamine oxide reductase of Shewanella oneidensis

We have isolated three Shewanella oneidensis mutants specifically impaired in trimethylamine oxide (TMAO) respiration. The mutations arose from insertions of an ISSo2 element into torA, torR, and torS, encoding, respectively, the TMAO reductase TorA, the response regulator TorR, and the sensor TorS. Although TorA is not the sole enzyme reducing TMAO in S. oneidensis, growth analysis showed that it is the main respiratory TMAO reductase. Use of a plasmid-borne torE'-lacZ fusion confirmed that the TorS-TorR phosphorelay mediates TMAO induction of the torECAD operon.     

Reduction of N-oxides and sulfoxide by the same terminal reductase inProteus mirabilis

Proteus mirabilis can grow anaerobically on the fermentable substrate, glucose. When the glucose medium was supplemented with an electron acceptor, growth doubled. However, the organism failed to grow anaerobically on the oxidizable substrate glycerol unless the medium was supplemented with an external electron acceptor. Dimethyl sulfoxide (DMSO), trimethylamine N-oxide (TMAO), nicotinamide N-oxide (NAMO), and nitrate (NO₃) can serve this function. Cell-free extracts ofP. mirabilis can reduce these compounds in the presence of various electron donors. In order to determine whether the same or different terminal reductase(s) are involved in the reduction of these compounds, we isolated mutants unable to grow on glycerol/DMSO medium. When these mutants were tested on glycerol medium containing TMAO, NAMO, and NO₃ as electron acceptors, it was found that there were two groups. Group I mutants were unable to grow with DMSO, TMAO, and NAMO, while their growth was unaffected with NO₃. Group II mutants were unable to grow on any electron acceptor including NO₃. Enzyme assays using reduced benzyl viologen with both groups of mutants were in agreement with growth studies. On the basis of these results, we conclude that the same terminal reductase is involved in the reduction of DMSO, TMAO, and NAMO (group I) and that the additional loss of NO₃ reductase in group II mutants is probably owing to a defect in the synthesis or insertion of molybdenum cofactor.     

Further characterization of trimethylamine N-oxide reductase from Escherichia coli, a molybdoprotein

Escherichia coli trimethylamine N-oxide (TMAO) reductase I, the major enzyme among inducible TMAO reductases, was purified to homogeneity by an improved method including heat treatment, ammonium sulfate precipitation, and chromatographies on Bio-Gel A-1.5m, DEAE-cellulose, and Reactive blue-agarose. The molecular weight was estimated by gel filtration to be approximately 200,000. A single subunit peptide with a molecular weight of 95,000 was found by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This enzyme contained 1.96 atoms of molybdenum, 0.96 atoms of iron, 1.52 atoms of zinc, and less than 0.4 atoms of acid-labile sulfur per molecular weight of 200,000. The absorption spectrum of the enzyme showed a peak at 278 nm and a shoulder at 288 nm, but no characteristic absorption was found from 350 to 700 nm. A fluorescent derivative of molybdenum cofactor was found when the enzyme was boiled with iodine in acidic solution; its fluorescence spectra were almost the same as those of the form A derivative of molybdopterin found in sulfite oxidase. The molybdenum cofactor released from heated TMAO reductase I reconstituted nitrate reductase in the extracts of Neurospora crassa mutant strain nit-1 lacking molybdenum cofactor. Thus, TMAO reductase I contains molybdopterin, which is a common constituent of some molybdenum-containing enzymes. Some kinetic properties were also determined.     

Purification and properties of trimethylamine N-oxide reductase from aerobic photosynthetic bacterium Roseobacter denitrificans.

Trimethylamine N-oxide (TMAO) reductase was purified from an aerobic photosynthetic bacterium Roseobacter denitrificans. The enzyme was purified from cell-free extract by ammonium sulfate fractionation, DEAE ion exchange chromatography, hydrophobic chromatography, and gel filtration. The purified enzyme was composed of two identical subunits with molecular weight of 90,000, as identified by SDS-polyacrylamide gel electrophoresis, containing heme c and a molybdenum cofactor. The molecular weight of the native enzyme determined by gel filtration was 172,000. The midpoint redox potential of heme c was +200 mV at pH 7.5. Absorption maxima appeared at 418,524, and 554 nm in the reduced state and 410 nm in the oxidized state. The enzyme reduced TMAO, nicotine acid N-oxide, picoline N-oxide, hydroxylamine, and bromate, but not dimethyl sulfoxide, methionine sulfoxide, chlorate, nitrate, or thiosulfate. Cytochrome c2 served as a direct electron donor. It probably catalyzes the electron transfer from cytochrome b-c1 complex to TMAO reductase. Cytochrome c552, another soluble low-molecular-weight cytochrome of this bacterium, also donated electrons directly to TMAO reductase.     

Enzymatic and physiological properties of the tungsten-substituted molybdenum TMAO reductase from Escherichia coli

The trimethylamine N-oxide (TMAO) reductase of Escherichia coli is a molybdoenzyme that catalyses the reduction of the TMAO to trimethylamine (TMA) with a redox potential of +130 mV. We have successfully substituted the molybdenum with tungsten and obtained an active tungsto-TMAO reductase. Kinetic studies revealed that the catalytic efficiency of the tungsto-substituted TMAO reductase (W-TorA) was increased significantly (twofold), although a decrease of about 50% in its kcat was found compared with the molybdo-TMAO reductase (Mo-TorA). W-TorA is more sensitive to high pH, is less sensitive to high NaCl concentration and is more heat resistant than Mo-TorA. Most importantly, the W-TorA becomes capable of reducing sulphoxides and supports the anaerobic growth of a bacterial host on these substrates. The evolutionary implication and mechanistic significance of the tungsten substitution are discussed.     

Influence of respiratory substrate on the cytochrome content of Shewanella putrefaciens

Shewanella putrefaciens can use trimethylamine oxide (TMAO) as electron acceptor under anoxic conditions. The associated cytochromes induced during growth under various respiratory conditions have been separated by liquid chromatography (DEAE Sepharose CL6b) and SDS-PAGE and characterized spectrophotometrically and by redox potentiometry. Two major low potential cytochromes and at least three minor low potential cytochromes, likely to be involved in TMAO reduction, were found. No cytochrome specific for TMAO reductase was found.     

Redox mechanisms in “oxidant-dependent” hexose fermentation by Rhodopseudomonas capsulata

Trimethylamine N-oxide (TMAO) can function as an electron acceptor in the anaerobic metabolism of both Rhodopseudomonas capsulata and Escherichia coli. In both bacteria, anaerobic growth in the presence of TMAO induces a system that can reduce TMAO to trimethylamine (TMA). Comparative studies, however, show that TMAO reduction serves different purposes in the organisms noted. In E. coli, anaerobic growth on sugars does not require the presence of TMAO, but in cells induced for TMAO reductase, TMAO can act as the terminal electron acceptor for membrane-associated oxidative phosphorylation. Anaerobic dark growth of R. capsulata is dependent on the presence of TMAO (or an analog) and in this organism a soluble system catalyzes anaerobic oxidation of NADH with TMAO. The mechanism, in R. capsulata, appears to involve a flavoprotein of the flavodoxin type and presumably represents a system for maintenance of redox balance during anaerobic dark fermentation of hexoses and related compounds.     

Isolation of transposon Tn5 insertion mutants of Rhodobacter capsulatus unable to reduce trimethylamine-N-oxide and dimethylsulphoxide

1) Rhodobacter capsulatus (formerly Rhodopseudomonas capsulata) strain 37b4 was subjected to transposon Tn5 mutagenesis. 2) Kanamycin-resistant transconjugants were screened for their inability to reduce trimethylamine-N-oxide (TMAO) as judged by the lack of alkali production during anaerobic growth on plates containing glucose as carbon source and cresol red as pH indicator. 3) Of 6 mutants examined, all were found to have considerably decreased levels of methylviologen-dependent TMAO reductase activity and dimethylsulphoxide (DMSO) reductase activity. 4) Periplasmic fractions of one of these mutants (DK9) and of the parent strain were subjected to sodium dodecylsulphate polyacrylamide gel electrophoresis. The gels were stained for TMAO-reductase and DMSO-reductase. With the wild-type strain, only a single polypeptide band, M_r=46,000, stained for TMAO and DMSO reductase activity. In mutant DK9 this band was not detectable. 5) In contrast to the parent strain, harvested washed cells of mutant DK9 were unable to generate a cytoplasmic membrane potential in the presence of TMAO or DMSO under dark anaerobic conditions. 6) In contrast to the parent strain, DK9 was unable to grow in dark anaerobic culture with fructose as the carbon source and TMAO as oxidant.Abbreviations TMAO trimethylamine-N-oxide - DMSO dimethylsulphoxide - PMS phenazine methosulphate - cytoplasmic membrane potential     

Cytochromes of the trimethylamine N-oxide anaerobic respiratory pathway of Escherichia coli

Escherichia coli grown anaerobically with trimethylamine N-oxide (TMAO) as a terminal electron acceptor develops a new cytochrome pathway in addition to the aerobic respiratory pathways which are still formed. Formate, NADH, and possibly other substrates derived from glucose, supply electrons to this pathway. Cytochromes with α-absorption peaks at about 548, 552, 554 and 557 nm are rapidly reoxidized by TMAO in a reaction which is not inhibited by 2-n-heptyl-4-hydroxyquinoneN-oxide. CuSO₄ inhibits the reoxidation by TMAO of the first two of these cytochromes. This suggests that the pathway of electron transfer leading to the reduction of TMAO is: substrates → cytochromes 548,552 → cytochromes 554,557 → trimethylamine-N-oxide reductase → TMAO. These cytochromes, but not those of the aerobic respiratory pathways, are reoxidized by the membrane-impermeant oxidant ammonium persulfate in intact cells. This suggests that the cytochromes of the TMAO reduction pathway and / or trimethylamine-N-oxide reductase are situated at the periplasmic surface of the cytoplasmic membrane of E. coli.     

Higher Circulating Trimethylamine N-oxide Sensitizes Sevoflurane-Induced Cognitive Dysfunction in Aged Rats Probably by Downregulating Hippocampal Methionine Sulfoxide Reductase A

Gut microbiota-derived metabolite trimethylamine N-oxide (TMAO) has recently been shown to promote oxidative stress and inflammation in the peripheral tissues, contributing to the pathogenesis of many diseases. Here we examined whether pre-existing higher circulating TMAO would influence cognitive function in aged rats after anesthetic sevoflurane exposure. Aged rats received vehicle or TMAO treatment for 3 weeks. After 2 weeks of treatment, these animals were exposed to either control or 2.6% sevoflurane for 4 h. One week after exposure, freezing as measured by fear conditioning test, microglia activity, proinflammatory cytokine expression and NADPH oxidase-dependent reactive oxygen species (ROS) production in the hippocampus (a key brain structure involved in learning and memory) were comparable between vehicle-treated rats exposed to control and vehicle-treated rats exposed to sevoflurane. TMAO treatment, which increased plasma TMAO before and 1 week after control or sevoflurane exposure, significantly reduced freezing to contextual fear conditioning, which was associated with increases in microglia activity, proinflammatory cytokine expression and NADPH oxidase-dependent ROS production in the hippocampus in rats exposed to sevoflurane but not in rats exposed to control. Moreover, hippocampal expression of antioxidant enzyme methionine sulfoxide reductase A (MsrA) was reduced by TMAO treatment in both groups, and TMAO-induced reduction in MsrA expression was negatively correlated with increased proinflammatory cytokine expression in rats exposed to SEV. These findings suggest that pre-existing higher circulating TMAO downregulates antioxidant enzyme MsrA in the hippocampus, which may sensitize the hippocampus to oxidative stress, resulting in microglia-mediated neuroinflammation and cognitive impairment in aged rats after sevoflurane exposure.

     

A novel sec-independent periplasmic protein translocation pathway in Escherichia coli.

The trimethylamine N-oxide (TMAO) reductase of Escherichia coli is a soluble periplasmic molybdoenzyme. The precursor of this enzyme possesses a cleavable N-terminal signal sequence which contains a twin-arginine motif. By using various moa, mob and mod mutants defective in different steps of molybdocofactor biosynthesis, we demonstrate that acquisition of the molybdocofactor in the cytoplasm is a prerequisite for the translocation of the TMAO reductase. The activation and translocation of the TMAO reductase precursor are post-translational processes, and activation is dissociable from translocation. The export of the TMAO reductase is driven mainly by the proton motive force, whereas sodium azide exhibits a limited effect on the export. The most intriguing observation is that translocation of the TMAO reductase across the cytoplasmic membrane is independent of the SecY, SecE, SecA and SecB proteins. Depletion of Ffh, a core component of the signal recognition particle of E. coli, appears to have a slight effect on the export of the TMAO reductase. These results strongly suggest that the translocation of the molybdoenzyme TMAO reductase into the periplasm uses a mechanism fundamentally different from general protein translocation.