Characterization of E. coli MG1655 and frdA and sdhC mutants at various aerobiosis levels

Depending on the availability of oxygen, Escherichia coli is able to switch between aerobic respiratory metabolism and anaerobic mixed acid fermentation. An important, yet understudied, metabolic mode is the micro-aerobic metabolism at intermediate oxygen availabilities. The relationship between oxygen input, physiology and gene expression of E. coli MG1655 and two isogenic mutants lacking succinate dehydrogenase (SDH) and fumarate reductase (FRD) activities was analyzed at different aerobiosis levels. Growth rate and cell yield were very similar to the parent strain. By-product formation was altered in the sdhC mutant to higher acetic acid and glutamate production in batch cultures. In continuous cultures with defined oxygen input gene expression analysis revealed a dependency of many catabolic genes to aerobiosis. Acetate excretion was still detectable under aerobic conditions in the sdhC mutant; the frdA mutant lacked anaerobic succinate excretion. Anaerobic repression of the sdh operon was diminished in the frdA strain, possibly to allow SDH to partially replace FRD. The experiments illustrate the remarkable adaptability of E. coli physiology—to compensate for the absence of important metabolic genes by altering carbon flux and/or gene expression such that there are only minor changes in growth capability across the aerobiosis range.     

Involvement of a gene of the chl E locus in the regulation of the nitrate reductase operon

Summary A strain of E. coli carrying a Mudl insertion leading to chlorate resistance was found to lack nitrate reductase and formate dehydrogenase activities, but to synthesize b-type cytochrome constitutively. Introduction of this insertion mutation into a strain bearing a fusion between the nitrate reductase operon (chl C, chl I) and the lac structural genes resulted in the constitutive expression of the lac genes of this last fusion. Identical results were found when the Mudl was eliminated promoting a deletion in the original insertion site. This mutation was located midway between gal and aro A, at the chl E locus. Study of a chl E strain already described revealed similar behaviour. Absence of nitrate reductase activity in these strains which constitutively express the structural genes of the nitrate reductase operon was tentatively attributed to the simultaneous lack of a cofactor of the nitrate reductase terminal enzyme, possibly cofactor Mo-X, and of a repressor of the operon.     

Reversible interconversion of the functional state of the gene regulator FNR from Escherichia coli in vivo by O2 and iron availability

FNR, the gene regulator of anaerobic respiratory genes of Escherichia coli is converted in vivo by O₂ and by chelating agents to an inactive state. The interconversion process was studied in vivo in a strain with temperature controlled synthesis of FNR by measuring the expression of the frd (fumarate reductase) operon and the reactivity of FNR with the alkylating agent iodoacetic acid. FNR from aerobic bacteria is, after arresting FNR synthesis and shifting to anaerobic conditions, able to activate frd expression and behaves in the alkylation assay like anaerobic FNR. After shift from anaerobic to aerobic conditions, FNR no longer activates the expression of frd and reacts similar to aerobic FNR in the alkylation assay. The conversion of aerobic (inactive) to anaerobic (active) FNR occurs in the presence of chloramphenicol, an inhibitor of protein synthesis. Anaerobic FNR can also be converted post-translationally to inactive, metal-depleted FNR by growing the bacteria in the presence of chelating agents. The reverse is also possible by incubating metal-depleted bacteria with Fe²⁺. From the experiments it is concluded that the aerobic and the metal-depleted form of FNR can be transferred post-translationally and reversibly to the anaerobic (active) form. The response of FNR to changes in O₂ supply therefore occurs at the FNR protein level in a reversible mode.Abbreviation BV_red = reduced benzyl viologen     

Anaerobic Expression of Escherichia coli Succinate Dehydrogenase: Functional Replacement of Fumarate Reductase in the Respiratory Chain during Anaerobic Growth

Succinate-ubiquinone oxidoreductase (SQR) from Escherichia coli is expressed maximally during aerobic growth, when it catalyzes the oxidation of succinate to fumarate in the tricarboxylic acid cycle and reduces ubiquinone in the membrane. The enzyme is similar in structure and function to fumarate reductase (menaquinol-fumarate oxidoreductase [QFR]), which participates in anaerobic respiration by E. coli. Fumarate reductase, which is proficient in succinate oxidation, is able to functionally replace SQR in aerobic respiration when conditions are used to allow the expression of the frdABCD operon aerobically. SQR has not previously been shown to be capable of supporting anaerobic growth of E. coli because expression of the enzyme complex is largely repressed by anaerobic conditions. In order to obtain expression of SQR anaerobically, plasmids which utilize the P_FRD promoter of the frdABCD operon fused to the sdhCDAB genes to drive expression were constructed. It was found that, under anaerobic growth conditions where fumarate is utilized as the terminal electron acceptor, SQR would function to support anaerobic growth of E. coli. The levels of amplification of SQR and QFR were similar under anaerobic growth conditions. The catalytic properties of SQR isolated from anaerobically grown cells were measured and found to be identical to those of enzyme produced aerobically. The anaerobic expression of SQR gave a greater yield of enzyme complex than was found in the membrane from aerobically grown cells under the conditions tested. In addition, it was found that anaerobic expression of SQR could saturate the capacity of the membrane for incorporation of enzyme complex. As has been seen with the amplified QFR complex, E. coli accommodates the excess SQR produced by increasing the amount of membrane. The excess membrane was found in tubular structures that could be seen in thin-section electron micrographs.     

Reduction of fumarate,mesaconate and crotonate by Mfr,a novel oxygen‐regulated periplasmic reductase in Campylobacter jejuni

Methylmenaquinol : fumarate reductase (Mfr) is a newly recognized type of fumarate reductase present in some ε‐proteobacteria, where the active site subunit (MfrA) is localized in the periplasm, but for which a physiological role has not been identified. We show that the Campylobacter jejuni mfrABE operon is transcribed from a single promoter, with the mfrA gene preceded by a small open reading‐frame (mfrX) encoding a C. jejuni‐specific polypeptide of unknown function. The growth characteristics and enzyme activities of mutants in the mfrA and menaquinol : fumarate reductase A (frdA) genes show that the cytoplasmic facing Frd enzyme is the major fumarate reductase under oxygen limitation. The Mfr enzyme is shown to be necessary for maximal rates of growth by fumarate respiration and rates of fumarate reduction in intact cells measured by both viologen assays and ¹H‐NMR were slower in an mfrA mutant. As periplasmic fumarate reduction does not require fumarate/succinate antiport, Mfr may allow more efficient adaptation to fumarate‐dependent growth. However, a further rationale for the periplasmic location of Mfr is suggested by the observation that the enzyme also reduces the fumarate analogues mesaconate and crotonate; fermentation products of anaerobes with which C. jejuni shares its gut environment, that are unable to be transported into the cell. Both MfrA and MfrB subunits were localized in the periplasm by immunoblotting and 2D‐gel electrophoresis, but an mfrE mutant accumulated unprocessed MfrA in the cytoplasm, suggesting a preassembled MfrABE holoenzyme has to be recognized by the TAT system for translocation to occur. Gene expression studies in chemostat cultures following an aerobic‐anaerobic shift showed that mfrA is highly upregulated by oxygen limitation, as would be experienced in vivo. Our results indicate that in addition to a role in fumarate respiration, Mfr allows C. jejuni to reduce analogous substrates specifically present in the host gut environment.     

Use of lac operon fusions to isolate Escherichia coli mutants with altered expression of the fumarate reductase system in response to substrate and respiratory controls.

Strains of $\text{E}\text{.}\text{coli}$ with fusions between the $\text{lac}$ structural genes and the promoter region of the fumarate reductase system were constructed from a parental strain deleted in the native $\text{lac}$ operon. Like fumarate reductase in wild-type cells, β-galactosidase in these fusion strains is inducible by fumarate, but only under anaerobic conditions. From one of these strains, three classes of mutants altered in the expression of the hybrid operon were isolated. By anaerobic selection for growth on lactose in the absence of fumarate, mutants that synthesize β-galactosidase constitutively both aerobically and anaerobically were obtained. By aerobic selection for growth on lactose in the presence of fumarate, mutants that are inducible in the enzyme both aerobically and anaerobically and mutants that are inducible in the enzyme only aerobically were obtained. The regulatory behaviors of the mutants studied suggest that substrate and respiratory control of the expression of the fumarate reductase complex are mechanistically connected.     

Regulation of the nitrate reductase operon: Effect of mutations in chl A, B, D and E genes

Summary Introduction of chlA, B or E mutant alleles into strains carrying fusions between the lac structural genes and the promoter of the nitrate reductase operon led to the partial or total constitutive expression of the fusion. Presence of chlD mutated alleles in the same strains did not result in constitutive expression of the fusion and allowed full induction by nitrate only in the presence of molybdenum. It is proposed that the molybdenum cofactor, Mo-X, of the nitrate reductase is also corepressor of the operon. The chlA, B and E genes would be involved in the biosynthesis of the X-moity. Mutations in these genes would give an altered X-moity which still binds to molybdenum but leads to a less effcient repressor complex; chlD gene would code for an enzyme inserting molybdenum in the X-moity of the cofactor. Mutations in chlD give an empty cofactor leading to a complex which permanently represses the operon unless molybdenum is added.     

The Quinol:Fumarate Oxidoreductase from the Sulphate Reducing Bacterium Desulfovibrio gigas: Spectroscopic and Redox Studies

The membrane bound fumarate reductase (FRD) from the sulphate-reducer Desulfovibrio gigas was purified from cells grown on a fumarate/sulphate medium and extensively characterized. The FRD is isolated with three subunits of apparent molecular masses of 71, 31, and 22 kDa. The enzyme is capable of both fumarate reduction and succinate oxidation, exhibiting a higher specificity toward fumarate (K _m for fumarate is 0.02 and for succinate 2 mM) and a reduction rate 30 times faster than that for oxidation. Studies by Visible and EPR spectroscopies allowed the identification of two B-type haems and the three iron–sulphur clusters usually found in FRDs and succinate dehydrogenases: [2Fe-2S]^2+/1+ (S1), [4Fe-4S]^2+/1+ (S2), and [3Fe-4S]^1+/0 (S3). The apparent macroscopic reduction potentials for the metal centers, at pH 7.6, were determined by redox titrations: –45 and –175 mV for the two haems, and +20 and –140 mV for the S3 and S1 clusters, respectively. The reduction potentials of the haem groups are pH dependent, supporting the proposal that fumarate reduction is associated with formation of the membrane proton gradient. Furthermore, co-reconstitution in liposomes of D. gigas FRD, duroquinone, and D. gigas cytochrome bd shows that this system is capable of coupling succinate oxidation with oxygen reduction to water.     

The anaerobic oxidation of dihydroorotate by Escherichia coli K-12

The oxidation of dihydroorotate under anaerobic conditions has been examined using various mutant strains of Escherichia coli K-12. This oxidation in cells grown anaerobically in a glucose minimal medium is linked via menaquinone to the fumarate reductase enzyme coded for by the frd gene and is independent of the cytochromes. The same dihydroorotate dehydrogenase protein functions in both the anaerobic and aerobic oxidation of dihydroorotate. Ferricyanide can act as an artificial electron acceptor for dihydroorotate dehydrogenase and the dihydroorotate-menaquinone-ferricyanide reductase activity can be solubilised by 2 M guanidine · HCl with little loss of activity.     

Nucleotide sequence and comparative analysis of the frd operon encoding the fumarate reductase of Proteus vulgaris. Extensive sequence divergence of the membrane anchors and absence of an frd-linked ampC cephalosporinase gene

The fumarate reductase of Escherichia coli is a bioenergetically important membrane-bound flavoenzyme consisting of four subunits. A and B comprise a membrane-extrinsic catalytic domain whereas C and D are hydrophobic polypeptides which link the catalytic centres to the electron-transport chain. The nucleotide sequence of the frd operon encoding the fumarate reductase of the distantly related bacterium, Proteus vulgaris has been determined and used to predict the primary structures of the respective subunits. Extensive amino acid sequence identity (greater than 80%) was found between the fumarate reductase A and B subunits of P. vulgaris and E. coli. In contrast, the primary structures of the P. vulgaris and E. coli C and D proteins are much less closely related (about 60% homology) although the overall hydrophobicity of their three membrane-spanning segments has been conserved. In most enteric bacteria, the frd operon is followed by genes, ampR and/or ampC, required for the genetic regulation and biosynthesis of a cephalosporinase. The corresponding region of the P. vulgaris genome is occupied by an operon (orf A'BCD) containing at least four genes which are clearly unrelated to the ampC system. Intriguingly the primary structures of the OrfA and OrfD proteins suggest that, like fumarate reductase, they may be components of a membrane-bound enzyme complex involved in energy metabolism.     

Growth of <Emphasis Type="Italic">E. coli</Emphasis> BL21 in minimal media with different gluconeogenic carbon sources and salt contents

Escherichia coli strain BL21 is commonly used as a host strain for protein expression and purification. For structural analysis, proteins are frequently isotopically labeled with deuterium (²H), ¹³C, or ¹⁵N by growing E. coli cultures in a medium containing the appropriate isotope. When large quantities of fully deuterated proteins are required, E. coli is often grown in minimal media with deuterated succinate or acetate as the carbon source because these are less expensive. Despite the widespread use of BL21, we found no data on the effect of different minimal media and carbon sources on BL21 growth. In this study, we assessed the growth behavior of E. coli BL21 in minimal media with different gluconeogenic carbon sources. Though BL21 grew reasonably well on glycerol and pyruvate, it had a prolonged lag-phase on succinate (20 h), acetate (10 h), and fumarate (20 h), attributed to the physiological adaptation of E. coli cells. Wild-type strain NCM3722 (K12) grew well on all the substrates. We also examined the growth of E. coli BL21 in minimal media that differed in their salt composition but not in their source of carbon. The commonly used M9 medium did not support the optimum growth of E. coli BL21 in minimal medium. The addition of ferrous sulphate to M9 medium (otherwise lacking it) increased the growth rate of E. coli cultures and significantly increased their cell density in the stationary phase. An erratum to this article can be found at     

The Role of Antioxidant Systems in the Response of Escherichia colito Heat Shock

Shifting the temperature from 30 to 45°C in an aerobic Escherichia coliculture inhibited the expression of the antioxidant genes katG, katE, sodA, and gor.The expression was evaluated by measuring -galactosidase activity in E. colistrains that contained fusions of the antioxidant gene promoters with the lacZoperon. Heat shock inhibited catalase and glutathione reductase, lowered the intracellular level of glutathione, and increased its extracellular level. It also suppressed the growth of mutants deficient in the katG-encoded catalase HPI, whereas the sensitivity of the wild-type andsodA sodBmutant cells to heat shock was almost the same. In the E. coliculture adapted to growth at 42°C, the content of both intracellular and extracellular glutathione was two times higher than in the culture grown at 30°C. The temperature-adapted cells grown aerobically at 42°C showed an increased ability to express the fused katG–lacZgenes.     

Laboratoire de Chimie Bactérienne C.N.R.S., Marsielle, France.

Summary Mutants of E. coli, completely devoid of nitrite reductase activity with glucose or formate as donor were studied. Biochemical analysis indicates that they are simultaneously affected in nitrate reductase, nitrite reductase, fumarate reductase and hydrogenase activities as well as in cytochrome c₅₅₂ biosynthesis. The use of an antiserum specific for nitrate reductase shows that the nitrate reductase protein is probably missing. A single mutation is responsible for this phenotype: the gene affected, nir R, is located close to tyr R i.e. at 29 min on the chromosomal map.Abbreviations BV Benzyl-Viologen - NTG N-methyl-N-nitro-N-nitrosoguanidine - NR nitrate reductase - NIR nitrite reductase - FR fumarate reductase - HYD hydrogenase - CYT c₅₅₂ cytochrome c₅₅₂     

Construction and Characterization of a 1,3-Propanediol Operon

The genes for the production of 1,3-propanediol (1,3-PD) in Klebsiella pneumoniae, dhaB, which encodes glycerol dehydratase, and dhaT, which encodes 1,3-PD oxidoreductase, are naturally under the control of two different promoters and are transcribed in different directions. These genes were reconfigured into an operon containing dhaB followed by dhaT under the control of a single promoter. The operon contains unique restriction sites to facilitate replacement of the promoter and other modifications. In a fed-batch cofermentation of glycerol and glucose, Escherichia coli containing the operon consumed 9.3 g of glycerol per liter and produced 6.3 g of 1,3-PD per liter. The fermentation had two distinct phases. In the first phase, significant cell growth occurred and the products were mainly 1,3-PD and acetate. In the second phase, very little growth occurred and the main products were 1,3-PD and pyruvate. The first enzyme in the 1,3-PD pathway, glycerol dehydratase, requires coenzyme B₁₂, which must be provided in E. coli fermentations. However, the amount of coenzyme B₁₂ needed was quite small, with 10 nM sufficient for good 1,3-PD production in batch cofermentations. 1,3-PD is a useful intermediate in the production of polyesters. The 1,3-PD operon was designed so that it can be readily modified for expression in other prokaryotic hosts; therefore, it is useful for metabolic engineering of 1,3-PD pathways from glycerol and other substrates such as glucose.     

Regulation of anaerobic respiratory pathways in Wolinella succinogenes by the presence of electron acceptors

In Wolinella succinogenes ATP synthesis and consequently bacterial growth can be driven by the reduction of either nitrate (E₀=+0.42 V), nitrite (E₀=+0.36 V), fumarate (E₀=+0.03 V) or sulphur (E₀=-0.27 V) with formate as the electron donor. Bacteria growing in the presence of nitrate and fumarate were found to reduce both acceptors simultaneously, while the reduction of both nitrate and fumarate is blocked during growth with sulphur. These observations were paralleled by the presence and absence of the corresponding bacterial reductase activities. Using a specific antiserum, fumarate reductase was shown to be present in bacteria grown with fumarate and nitrate, and to be nearly absent from bacteria grown in the presence of sulphur. The contents of polysulphide reductase, too, corresponded to the enzyme activities found in the bacteria. This suggests that the activities of anaerobic respiration are regulated at the biosynthetic level in W. succinogenes. Thus nitrate and fumarate reduction are repressed by the most electronegative acceptor of anacrobic respiration, sulphur. By contrast, in Escherichia coli a similar effect is exerted by the most electropositive acceptor, O₂. W. succinogenes also differs from E. coli in that fumarate reductase is not repressed by nitrate.Abbreviations BV benzyl viologen - DMN 2,3-dimethyl-1,4-naphthoquinone - DMSO dimethylsulfoxide - TMAO trimethylamine-N-oxide     

A novel regulatory circuit to control indole biosynthesis protects Escherichia coli from nitrosative damages during the anaerobic respiration of nitrate

Indole is a widely distributed microbial secondary metabolite. It mediates a broad range of physiological processes in both its producing and surrounding species. Yet, indole biosynthesis during the anaerobiosis of bacteria remains largely uncharacterized. Here, we find that while indole production is promoted during fermentation and anaerobic respiration of fumarate and trimethylamine N‐oxide in E. coli, its biosynthesis is repressed during anaerobic respiration of nitrate especially during exponential growth. We show that expression of the indole biosynthetic operon tnaCAB is repressed under this condition by the two component systems NarXL and NarPQ in the global regulator FNR dependent manner. During stationary growth phase of nitrate respiration, indole biosynthesis is derepressed. However, cellular indole concentration remains low. We demonstrate that this is due to the rapid conversion of indole into mutagenic indole nitrosative derivatives under this condition. Consistent with this, a supplement of exogenous indole during nitrate respiration causes elevated mutation frequencies in E. coli cells lacking the detoxifying efflux genes mdtEF, and ectopic over‐expression of tnaAB genes decreases the fitness of E. coli to this physiological condition. Together, these results suggest that indole production is tuned to the bioenergetics activities of E. coli to facilitate its adaptation and fitness.     

A genetical and biochemical study of chlorate-resistant mutants ofSalmonella typhimurium

S.typhimurium can form nitrate reductase A, chlorate reductase C, thiosulfate reductase, tetrathionate reductase and formic dehydrogenase. None of these enzymes are formed in chlorate-resistant mutants. Conjugation experiments showed the presence of a strong linkage between thechl andgal markers of the bacterial chromosome. By deletion mapping the gene ordernic A aro G gal bio chl D uvr B chl A was found. Strains with deletions terminating betweenbio anduvr B or betweenuvr B andchl A have a number of aberrant properties. Though resistant against chlorate they reduce nitrate and form gas. After growth with nitrate they form less nitrate reductase than the wild type which may explain the resistance against chlorate. After growth with thiosulfate they form small amounts of thiosulfate reductase and chlorate reductase C. In crosses between anE.coli Hfrchl ⁺ strain and aS.typhimurium chl A strain recombinants were obtained, forming nitrate reductase A and chlorate reductase C. These recombinants do not form gas, which indicates that thechl ⁺ gene fromE.coli does not function normally inS.typhimurium.The author is very gratefull to Miss C. W. Bettenhaussen, Miss W. M. C. Kapteijn and Mr. K. Pietersma for technical assistance. Helpfull suggestions of Dr. P. van de Putte (Medical Biological Laboratory of the National Defence Organization TNO, Rijswijk) are gratefully acknowledged.     

Expression of the Klebsiella pneumoniae CG21 acetoin reductase gene in Clostridium acetobutylicum ATCC 824

Acetoin reductase catalyzes the production of 2,3-butanediol from acetoin. The gene encoding the acetoin reductase of Klebsiella pneumoniae CG21 was cloned and expressed in Escherichia coli and Clostridium acetobutylicum ATCC 824. The nucleotide sequence of the gene encoding the enzyme was determined to be 768 bp long. Expression of the K. pneumoniae acetoin reductase gene in E. coli revealed that the enzyme has a molecular mass of about 31,000 Da based on sodium dodecyl sulfate polyacrylamide gel electrophoresis analysis. The K. pneumoniae acetoin reductase gene was cloned into a clostridial/E. coli shuttle vector, and expression of the gene resulted in detectable levels of acetoin reductase activity in both E. coli and C. acetobutylicum. While acetoin, the natural substrate of acetoin reductase, is a typical product of fermentation by C. acetobutylicum, 2,3-butanediol is not. Analysis of culture supernatants by gas chromatography revealed that introduction of the K. pneumoniae acetoin reductase gene into C. acetobutylicum was not sufficient for 2,3-butanediol production even though the cultures were producing acetoin. 2,3-Butanediol was produced by cultures of C. acetobutylicum containing the gene only when commercial acetoin was added. Journal of Industrial Microbiology & Biotechnology (2001) 27, 220–227. Received 12 September 2000/ Accepted in revised form 26 June 2001