Regulation of the trimethylamine N-oxide (TMAO) reductase in Escherichia coli: analysis of tor::Mud1 operon fusion

Summary Mud1 insertion mutants of Escherichia coli were obtained in which the lac structural genes were fused to the promoter of torA, a gene encoding the trimethylamine N-oxide (TMAO) reductase. Expression of the fusion is induced by TMAO and repressed by oxygen. However, in contrast to the nar operon which codes for the nitrate reductase structural genes, the tor::Mud1 fusion was found to be independent of the positive control exerted by the nirR gene product and not repressed by the molybdenum cofactor. The torA gene which is strongly linked to pyrF (28.3 U) is different from any tor gene already described in E. coli or in Salmonella typhimurium.     

Anaerobic induction of trimethylamine N-oxide reductase and cytochromes by dimethyl sulfoxide inEscherichia coli

Reduction of trimethylamine N-oxide is catalyzed by at least two enzymes inEscherichia coli: trimethylamine N-oxide reductase, which is anaerobically induced by trimethylamine N-oxide, and the constitutive enzyme dimethyl sulfoxide reductase. In this study, an increase in the specific activity of trimethylamine N-oxide reduction was observed in the anaerobic culture with dimethyl sulfoxide, but the specific activity of dimethyl sulfoxide reduction was not changed. The inducible enzyme trimethylamine N-oxide reductase was found in this culture. A marked expression of the structural genetorA for trimethylamine N-oxide reductase was also observed in atorA-lacZ gene fusion strain under anaerobic conditions with either trimethylamine N-oxide or dimethyl sulfoxide.l-Methionine sulfoxide and the N-oxides of adenosine, picolines, and nicotinamide slightly repressed expression of the gene. Membrane-boundb- andc-type cytochromes involved in the trimethylamine N-oxide reduction were also produced in a wild-type strain grown anaerobically with dimethyl sulfoxide. But thec-type cytochrome was not produced in thetorA-lacZ strain grown anaerobically with trimethylamine N-oxide or dimethyl sulfoxide; this suggests that there is a correlation between the expression oftorA and the synthesis of the cytochrome.     

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     

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.     

An Escherichia coli mutant containing only demethylmenaquinone,but no menaquinone: effects on fumarate,dimethylsulfoxide, trimethylamine N-oxide and nitrate respiration

The mutant strain AN70 (ubiE) of Escherichia coli which is known to lack ubiquinone (Young IG et al. 1971), was analyzed for menaquinone (MK) and demethylmenaquinone (DMK) contents. In contrast to the wild-type, strain AN70 contained only DMK, but no MK. The mutant strain was able to grow with fumarate, trimethylamine N-oxide (TMAO) and dimethylsulfoxide (DMSO), but not with nitrate as electron acceptor. The membranes catalyzed anaerobic respiration with fumarate and TMAO at 69 and 74% of wild-type rates. DMSO respiration was reduced to 38% of wild-type activities and nitrate respiration was missing (8% of wild-type), although the respective enzymes were present in wild-type rates. The results complement earlier findings which demonstrated a role for DMK only in TMAO respiration (Wissenbach et al. 1990). It is concluded, that DMK (in addition to MK) can serve as a redox mediator in fumarate, TMAO and to some extent in DMSO respiration, but not in nitrate respiration. In strain AN70 (ubiE) the lack of ubiquinone (Q) is due to a defect in a specific methylation step of Q biosynthesis. Synthesis of MK from DMK appears to depend on the same gene (ubiE).Abbreviations DMSO = dimethylsulfoxide - DMS = dimethylsulfide - TMAO = trimethylamine N-oxide - TMA = trimethylamine - BV = benzylviologen - BV_red = reduced benzylyiologen - Q = ubiquinone - MK = menaquinone - DMK = demethylmenaquinone - NQ = naphthoquinone     

Electron donors and the quinone involved in dimethyl sulfoxide reduction inEscherichia coli

Escherichia coli can use dimethyl sulfoxide (DMSO) as an electron acceptor during anaerobic growth on the oxidizable substrate, glycerol. During growth, the DMSO is reduced to dimethyl sulfide (DMS). For the reduction of DMSO, NADH, formate, lactate, reduced benzyl viologen, reduced methyl viologen, and dithionite can serve as electron donors. The terminal reductase and the dehydrogenases linking the various electron donors to the electron transport chain were found to be membrane bound. Chlorate-resistant mutants (chl) were unable to grow and reduce DMSO. However, in the case of thechlD mutant, growth and DMSO reduction can be restored by growth in the presence of high concentrations of molybdate. Mutants ofE. coli blocked in menaquinone (vitamin K₂) biosynthesis—menB, menC, andmenD—were unable to grow with DMSO as an electron acceptor, even though the terminal reductase is present in these mutants. Both growth and DMSO reduction could be restored in these mutants by growth in the presence of the menaquinone intermediates,o-succinylbenzoate and 1,4-dihydroxy-2-naphthoate, depending on the metabolic block of the mutant. Thus menaquinone is involved in electron transport during DMSO reduction.     

Dimethyl sulfoxide reductase is not required for trimethylamine N-oxide reduction in Escherichia chcoli

Deletion mutants of Escherichia coli lacking dimethyl sulfoxide (DMSO) reductase activity and consequently unable to utilize DMSO as an electron acceptor for anaerobic growth have been isolated. These mutants retained the ability to use trimethylamine N-oxide (TMAO) as an electron acceptor and the TMAO reductase activity was found to be unaltered. Heating the cell-free extract of the wild-type strain at 70 degrees C for 15 min selectively inactivated the DMSO reductase activity while the TMAO reductase activity remained unchanged for at least 1 h.     

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.     

Oxygen and nitrate-dependent regulation of <Emphasis Type="Italic">dmsABC</Emphasis> operon expression in <Emphasis Type="Italic">Escherichia coli</Emphasis>: sites for Fnr and NarL protein interactions

Background  

Escherichia coli can respire anaerobically using dimethyl sulfoxide (DMSO) or trimethylamine-N-oxide (TMAO) as the terminal electron acceptor for anaerobic energy generation. Expression of the dmsABC genes that encode the membrane-associated DMSO/TMAO reductase is positively regulated during anaerobic conditions by the Fnr protein and negatively regulated by the NarL protein when nitrate is present.     

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     

The specific functions of menaquinone and demethylmenaquinone in anaerobic respiration with fumarate,dimethylsulfoxide, trimethylamine N-oxide and nitrate by Escherichia coli

The respiratory activities of E. coli with H₂ as donor and with nitrate, fumarate, dimethylsulfoxide (DMSO) or trimethylamine N-oxide (TMAO) as acceptor were measured using the membrane fraction of quinone deficient strains. The specific activities of the membrane fraction lacking naphthoquinones with fumarate, DMSO or TMAO amounted to 2% of those measured with the membrane fraction of the wild-type strain. After incorporation of vitamin K₁ [instead of menaquinone (MK)] into the membrane fraction deficient of naphthoquinones, the activities with fumarate or DMSO were 92% or 17%, respectively, of the activities which could be theoretically achieved. Incorporation of demethylmenaquinone (DMK) did not lead to a stimulation of the activities of the mutant. In contrast, the electron transport activity with TMAO was stimulated by the incorporation of either vitamin K₁ or DMK. Nitrate respiration was fully active in membrane fractions lacking either naphthoquinones or Q, but was 3% of the wild-type activity, when all quinones were missing. Nitrate respiration was stimulated on the incorporation of either vitamin K₁ or Q into the membrane fraction lacking quinones, while the incorporation of DMK was without effect. These results suggest that MK is specifically involved in the electron transport chains catalyzing the reduction of fumarate or DMSO, while either MK or DMK serve as mediators in TMAO reduction. Nitrate respiration requires either Q or MK.Abbreviations DMK demethylmenaquinone - MK menaquinone - Q ubiquinone - DMSO dimethylsulfoxide - TMAO trimethylamine N-oxide - DMS dimethylsulfide - TMA trimethylamine - BV benzylviologen     

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.     

Activation of Cholera Toxin Production by Anaerobic Respiration of Trimethylamine N-oxide in Vibrio cholerae

Vibrio cholerae is a Gram-negative bacterium that causes cholera. Although the pathogenesis caused by this deadly pathogen takes place in the intestine, commonly thought to be anaerobic, anaerobiosis-induced virulence regulations are not fully elucidated. Anerobic growth of the V. cholerae strain, N16961, was promoted when trimethylamine N-oxide (TMAO) was used as an alternative electron acceptor. Strikingly, cholera toxin (CT) production was markedly induced during anaerobic TMAO respiration. N16961 mutants unable to metabolize TMAO were incapable of producing CT, suggesting a mechanistic link between anaerobic TMAO respiration and CT production. TMAO reductase is transported to the periplasm via the twin arginine transport (TAT) system. A similar defect in both anaerobic TMAO respiration and CT production was also observed in a N16961 TAT mutant. In contrast, the abilities to grow on TMAO and to produce CT were not affected in a mutant of the general secretion pathway. This suggests that V. cholerae may utilize the TAT system to secrete CT during TMAO respiration. During anaerobic growth with TMAO, N16961 cells exhibit green fluorescence when stained with 2′,7′-dichlorofluorescein diacetate, a specific dye for reactive oxygen species (ROS). Furthermore, CT production was decreased in the presence of an ROS scavenger suggesting a positive role of ROS in regulating CT production. When TMAO was co-administered to infant mice infected with N16961, the mice exhibited more severe pathogenic symptoms. Together, our results reveal a novel anaerobic growth condition that stimulates V. cholerae to produce its major virulence factor.     

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.     

Characterization of genes encoding dimethyl sulfoxide reductase of Rhodobacter sphaeroides 2.4.1T: an essential metabolic gene function encoded on chromosome II.

Rhodobacter sphaeroides 2.4.1T is a purple nonsulfur facultative phototrophic bacterium which exhibits remarkable metabolic diversity as well as genomic complexity. Under anoxic conditions, in the absence of light and the presence of dimethyl sulfoxide (DMSO) or trimethylamine N-oxide (TMAO), R. sphaeroides 2.4.1T utilizes DMSO or TMAO as the terminal electron acceptor for anaerobic respiration, which is mediated by the molybdoenzyme DMSO reductase. Sequencing of a 13-kb region of chromosome II revealed the presence of 10 putative open reading frames, of which 5 possess homology to genes encoding the TMAO reductase (the tor system) of Escherichia coli. The dorS and dorR genes encode a sensor-regulator pair of the two-component sensory transduction protein family, homologous to the torS and torR gene products. The dorC gene was shown to encode a 44-kDa DMSO-inducible c-type cytochrome. The dorB gene encodes a membrane protein of unknown function homologous to the torD gene product. The dorA gene encodes DMSO reductase, containing the molybdopterin active site. Mutations were constructed in each of these dor genes, and the resulting mutants were shown to be impaired for DMSO-dependent anaerobic growth in the dark. The mutant strains exhibited negligible levels of DMSO reductase activity compared to the wild-type strain under similar growth conditions. Further, no DorA protein was detected in DorS and DorR mutant strains with anti-DorA antisera, suggesting that the products of these genes are required for the positive regulation of dor expression in response to DMSO. This characterization of the dor gene cluster is the first evidence that genes of chromosome CII encode metabolic functions which are essential under particular growth conditions.     

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.     

The biogenesis of c-type cytochromes in Escherichia coli requires a membrane-bound protein, DipZ, with a protein disulphide isomerase-like domain

A mutant of Escherichia coli K-12, JCB606, which lacks all five c-type cytochromes synthesized during anaerobic growth in the presence of nitrite or tri-methylamine-N-oxide (TMAO), was totally defective in Nrf activity and also partially defective in TMAO reductase activity. The mutation in strain JCB606 was shown to affect expression of the tor operon, which contributes almost equally with the products of the dms operon to the rate of TMAO reduction by bacteria during anaerobic growth in the presence of TMAO. The mutation in strain JCB606, dipZ, was mapped by P1 transduction close to the mel operon at co-ordinate 4425 on the E. coli chromosome, the gene order being nrf–fdhF–mel–dipZ–ampC. Recombinant plasmids that restored Nrf activity to test-tube cultures of the mutant were isolated from a cosmid library. A 2.7 kb EcoRV–Smal fragment (co-ordinates 4443 to 4446 kb on the physical map of the E. coli chromosome) was found potentially to encode three genes arranged in at least two operons. The second gene, dipZ, was sufficient to complement the JCB606 mutation. The translated DNA sequence predicts that DipZ is a 53kDa integral membrane protein with a 37kDa N-terminal domain including at least six membrane-spanning helices and a 16kDa carboxy-terminal hydrophilic domain which includes a protein disulphide isomerase-like motif. It is suggested that DipZ is essential for maintaining cytochrome c apoproteins in the correct conformations for the covalent attachment of haem groups to the appropriate pairs of cysteine residues.