Regulation of the adhE gene, which encodes ethanol dehydrogenase in Escherichia coli

Two-stage dynamic deregulation of metabolism improves process robustness & scalability in engineered E. coli

We report that two-stage dynamic control improves bioprocess robustness as a result of the dynamic deregulation of central metabolism. Dynamic control is implemented during stationary phase using combinations of CRISPR interference and controlled proteolysis to reduce levels of central metabolic enzymes. Reducing the levels of key enzymes alters metabolite pools resulting in deregulation of the metabolic network. Deregulated networks are less sensitive to environmental conditions improving process robustness. Process robustness in turn leads to predictable scalability, minimizing the need for traditional process optimization. We validate process robustness and scalability of strains and bioprocesses synthesizing the important industrial chemicals alanine, citramalate and xylitol. Predictive high throughput approaches that translate to larger scales are critical for metabolic engineering programs to truly take advantage of the rapidly increasing throughput and decreasing costs of synthetic biology.

Comparison of Glucose, Acetate and Ethanol as Carbon Resource for Production of Poly(3-Hydroxybutyrate) and Other Acetyl-CoA Derivatives

Poly(3-hydroxybutyrate) (PHB) is a biodegradable and biocompatible thermoplastic, and synthesized from the central metabolite acetyl-CoA. The acetyl-CoA synthesis from glucose presents low atomic economy due to the release of CO₂ in pyruvate decarboxylation. As ethanol and acetate can be converted into acetyl-CoA directly, they were used as carbon source for PHB production in this study. The reductase mutant AdhE A267T/E568K was introduced into Escherichia coli to enable growth on ethanol, and acetate utilization was improved by overexpression of acetyl-CoA synthetase ACS. Comparison of the PHB production using glucose, ethanol or acetate as sole carbon source showed that the production and yield from ethanol was much higher than those from glucose and acetate, and metabolome analysis revealed the differences in metabolism of glucose, ethanol and acetate. Furthermore, other acetyl-CoA derived chemicals including 3-hydroxypropionate and phloroglucinol were produced from those three feedstocks, and similar results were achieved, suggesting that ethanol could be a suitable carbon source for the production of acetyl-CoA derivatives.

AcrR and Rex Control Mannitol and Sorbitol Utilization through Their Cross-Regulation of Aldehyde-Alcohol Dehydrogenase (AdhE) in Lactobacillus plantarum

Lactobacillus plantarum is a versatile bacterium that occupies a wide range of environmental niches. In this study, we found that a bifunctional aldehyde-alcohol dehydrogenase-encoding gene, adhE, was responsible for L. plantarum being able to utilize mannitol and sorbitol through cross-regulation by two DNA-binding regulators. In L. plantarum NF92, adhE was greatly induced, and the growth of an adhE-disrupted (ΔadhE) strain was repressed when sorbitol or mannitol instead of glucose was used as a carbon source. The results of enzyme activity and metabolite assays demonstrated that AdhE could catalyze the synthesis of ethanol in L. plantarum NF92 when sorbitol or mannitol was used as the carbon source. AcrR and Rex were two transcriptional factors screened by an affinity isolation method and verified to regulate the expression of adhE DNase I footprinting assay results showed that they shared a binding site (GTTCATTAATGAAC) in the adhE promoter. Overexpression and knockout of AcrR showed that AcrR was a novel regulator to promote the transcription of adhE The activator AcrR and repressor Rex may cross-regulate adhE when L. plantarum NF92 utilizes sorbitol or mannitol. Thus, a model of the control of adhE by AcrR and Rex during L. plantarum NF92 utilization of mannitol or sorbitol was proposed.IMPORTANCE The function and regulation of AdhE in the important probiotic genus Lactobacillus are rarely reported. Here we demonstrated that AdhE is responsible for sorbitol and mannitol utilization and is cross-regulated by two transcriptional regulators in L. plantarum NF92, which had not been reported previously. This is important for L. plantarum to compete and survive in some harsh environments in which sorbitol or mannitol could be used as carbon source. A novel transcriptional regulator AcrR was identified to be important to promote the expression of adhE, which was unknown before. The cross-regulation of adhE by AcrR and Rex is important to balance the level of NADH in the cell during sorbitol or mannitol utilization.

Fermentative Pyruvate and Acetyl-Coenzyme A Metabolism

Pyruvate and acetyl-CoA form the backbone of central metabolism. The nonoxidative cleavage of pyruvate to acetyl-CoA and formate by the glycyl radical enzyme pyruvate formate lyase is one of the signature reactions of mixed-acid fermentation in enterobacteria. Under these conditions, formic acid accounts for up to one-third of the carbon derived from glucose. The further metabolism of acetyl-CoA to acetate via acetyl-phosphate catalyzed by phosphotransacetylase and acetate kinase is an exemplar of substrate-level phosphorylation. Acetyl-CoA can also be used as an acceptor of the reducing equivalents generated during glycolysis, whereby ethanol is formed by the polymeric acetaldehyde/alcohol dehydrogenase (AdhE) enzyme. The metabolism of acetyl-CoA via either the acetate or the ethanol branches is governed by the cellular demand for ATP and the necessity to reoxidize NADH. Consequently, in the absence of an electron acceptor mutants lacking either branch of acetyl-CoA metabolism fail to cleave pyruvate, despite the presence of PFL, and instead reduce it to D-lactate by the D-lactate dehydrogenase. The conversion of PFL to the active, radical-bearing species is controlled by a radical-SAM enzyme, PFL-activase. All of these reactions are regulated in response to the prevalent cellular NADH:NAD+ ratio. In contrast to Escherichia coli and Salmonella species, some genera of enterobacteria, e.g., Klebsiella and Enterobacter, produce the more neutral product 2,3-butanediol and considerable amounts of CO2 as fermentation products. In these bacteria, two molecules of pyruvate are converted to α-acetolactate (AL) by α-acetolactate synthase (ALS). AL is then decarboxylated and subsequently reduced to the product 2,3-butandiol.

A secondary structure in the 5' untranslated region of adhE mRNA required for RNase G-dependent regulation

Escherichia coli RNase G is involved in the degradation of several mRNAs, including adhE and eno, which encode alcohol dehydrogenase and enolase respectively. Previous research indicates that the 5' untranslated region (5'-UTR) of adhE mRNA gives RNase G-dependency to lacZ mRNA when tagged at the 5'-end, but it has not been elucidated yet how RNase G recognizes adhE mRNA. Primer extension analysis revealed that RNase G cleaved a phosphodiester bond between -19A and -18C in the 5'-UTR (the A of the start codon was defined as +1). Site-directed mutagenesis indicated that RNase G did not recognize the nucleotides at -19 and -18. Random deletion analysis indicated that the sequence from -145 to -125 was required for RNase G-dependent degradation. Secondary structure prediction and further site-directed deletion suggested that the stem-loop structure, with a bubble in the stem, is required for RNaseG-dependent degradation of adhE mRNA.

The path to next generation biofuels: successes and challenges in the era of synthetic biology

Volatility of oil prices along with major concerns about climate change, oil supply security and depleting reserves have sparked renewed interest in the production of fuels from renewable resources. Recent advances in synthetic biology provide new tools for metabolic engineers to direct their strategies and construct optimal biocatalysts for the sustainable production of biofuels. Metabolic engineering and synthetic biology efforts entailing the engineering of native and de novo pathways for conversion of biomass constituents to short-chain alcohols and advanced biofuels are herewith reviewed. In the foreseeable future, formal integration of functional genomics and systems biology with synthetic biology and metabolic engineering will undoubtedly support the discovery, characterization, and engineering of new metabolic routes and more efficient microbial systems for the production of biofuels.

Escherichia coli Dps interacts with DnaA protein to impede initiation: a model of adaptive mutation

During exponential growth, the level of Dps transiently increases in response to oxidative stress to sequester and oxidize Fe2+, which would otherwise lead to hydroxyl radicals that damage the bacterial chromosome. We report that Dps specifically interacts with DnaA protein by affinity chromatography and a solid phase binding assay, requiring the N-terminal region of DnaA to interact. In vitro, Dps inhibits DnaA function in initiation by interfering with strand opening of the replication origin. Comparing isogenic dps+ and dps::kan strains by flow cytometry and by quantitative polymerase chain reaction assays at either the chromosomally encoded level, or at an elevated level encoded by an inducible plasmid, we show that Dps causes less frequent initiations. Results from genetic experiments support this conclusion. We suggest that Dps acts as a checkpoint during oxidative stress to reduce initiations, providing an opportunity for mechanisms to repair oxidative DNA damage. Because Dps does not block initiations absolutely, duplication of the damaged DNA is expected to increase the genetic variation of a population, and the probability that genetic adaptation leads to survival under conditions of oxidative stress.

Genome-wide expression analysis indicates that FNR of Escherichia coli K-12 regulates a large number of genes of unknown function

The major regulator controlling the physiological switch between aerobic and anaerobic growth conditions in Escherichia coli is the DNA binding protein FNR. To identify genes controlled by FNR, we used Affymetrix Antisense GeneChips to compare global gene expression profiles from isogenic MG1655 wild-type and Deltafnr strains grown in glucose minimal media under aerobic or anaerobic conditions. We found that 297 genes contained within 184 operons were regulated by FNR and/or by O2 levels. The expression of many genes known to be involved in anaerobic respiration and fermentation was increased under anaerobic growth conditions, while that of genes involved in aerobic respiration and the tricarboxylic acid cycle were repressed as expected. The expression of nine operons associated with acid resistance was also increased under anaerobic growth conditions, which may reflect the production of acidic fermentation products. Ninety-one genes with no presently defined function were also altered in expression, including seven of the most highly anaerobically induced genes, six of which we found to be directly regulated by FNR. Classification of the 297 genes into eight groups by k-means clustering analysis indicated that genes with common gene expression patterns also had a strong functional relationship, providing clues for studying the function of unknown genes in each group. Six of the eight groups showed regulation by FNR; while some expression groups represent genes that are simply activated or repressed by FNR, others, such as those encoding functions for chemotaxis and motility, showed a more complex pattern of regulation. A computer search for FNR DNA binding sites within predicted promoter regions identified 63 new sites for 54 genes. We suggest that E. coli MG1655 has a larger metabolic potential under anaerobic conditions than has been previously recognized.

Novel antioxidant role of alcohol dehydrogenase E from Escherichia coli

Alcohol dehydrogenase E (AdhE) is an Fe-enzyme that, under anaerobic conditions, is involved in dissimilation of glucose. The enzyme is also present under aerobic conditions, its amount is about one-third and its activity is only one-tenth of the values observed under anaerobic conditions. Nevertheless, its function in the presence of oxygen remained ignored. The data presented in this paper led us to propose that the enzyme has a protective role against oxidative stress. Our results indicated that cells deleted in adhE gene could not grow aerobically in minimal media, were extremely sensitive to oxidative stress and showed division defects. In addition, compared with wild type, mutant cells displayed increased levels of internal peroxides (even higher than those found in a Delta katG strain) and increased protein carbonyl content. This pleiotropic phenotype disappeared when the adhE gene was reintroduced into the defective strain. The purified enzyme was highly reactive with hydrogen peroxide (with a Ki of 5 microM), causing inactivation due to a metal-catalyzed oxidation reaction. It is possible to prevent this reactivity to hydrogen peroxide by zinc, which can replace the iron atom at the catalytic site of AdhE. This can also be achieved by addition of ZnSO4 to cell cultures. In such conditions, addition of hydrogen peroxide resulted in reduced cell viability compared with that obtained without the Zn treatment. We therefore propose that AdhE acts as a H2O2 scavenger in Escherichia coli cells grown under aerobic conditions.

Sequences affecting the regulation of solvent production in Clostridium acetobutylicum

The high solvent phenotype of Clostridium acetobutylicum mutants B and H was complemented by the introduction of a plasmid that contains either an intact or partially-deleted copy of solR, restoring acetone and butanol production to wild-type levels. This demonstrates that the solR open reading frame on pSOLThi is not required to restore solvent levels. The promoter region upstream of alcohol dehydrogense E (adhE) was examined in efforts to identify sites that play major roles in the control of expression. A series of adhE promoter fragments was constructed and the expression of each in acid- and solvent-phases of growth was analyzed using a chloramphenicol acetyl-transferase reporter system. Our results show that a region beyond the 0A box is needed for full induction of the promoter. Additionally, we show that the presence of sequences around a possible processing site designated S2 may have a negative role in the regulation of adhE expression.

Poly(3-hydroxybutyrate) (PHB) synthesis by recombinant Escherichia coli harbouring Streptomyces aureofaciens PHB biosynthesis genes: effect of various carbon and nitrogen sources

Recombinant Escherichia coli (ATCC:PTA-1579) harbouring poly(3-hydroxybutyrate) (PHB) synthesising genes from Streptomyces aureofaciens NRRL 2209 accumulates PHB. Effects of different carbon and nitrogen sources on PHB accumulation by recombinant E. coli were studied. Among the carbon sources used glycerol, glucose, palm oil and ethanol supported PHB accumulation. No PHB accumulated in recombinant cells when sucrose or molasses were used as carbon source. Yeast extract, peptone, a combination of yeast extract and peptone, and corn steep liquor were used as nitrogen sources. The maximum PHB accumulation (60% of cell dry weight) was measured after 48 h of cell growth at 37 degrees C in a medium with glycerol as the sole carbon source, and yeast extract and peptone as nitrogen sources. Scanning electron microscopy of the PHB granules isolated from recombinant E. coli revealed these to be spherical in shape with a diameter ranging from 0.11 to 0.35 pm with the mean value of 0.23 +/- 0.06 pm.

DnaK dependence of mutant ethanol oxidoreductases evolved for aerobic function and protective role of the chaperone against protein oxidative damage in Escherichia coli

The adhE gene of Escherichia coli encodes a multifunctional ethanol oxidoreductase (AdhE) that catalyzes successive reductions of acetyl-CoA to acetaldehyde and then to ethanol reversibly at the expense of NADH. Mutant JE52, serially selected for acquired and improved ability to grow aerobically on ethanol, synthesized an AdhE(A267T/E568K) with two amino acid substitutions that sequentially conferred improved catalytic properties and stability. Here we show that the aerobic growth ability on ethanol depends also on protection of the mutant AdhE against metal-catalyzed oxidation by the chaperone DnaK (a member of the Hsp70 family). No DnaK protection of the enzyme is evident during anaerobic growth on glucose. Synthesis of DnaK also protected E. coli from H2O2 killing under conditions when functional AdhE is not required. Our results therefore suggest that, in addition to the known role of protecting cells against heat stress, DnaK also protects numerous kinds of proteins from oxidative damage.

Evolution of the adhE gene product of Escherichia coli from a functional reductase to a dehydrogenase. Genetic and biochemical studies of the mutant proteins

The multifunctional AdhE protein of Escherichia coli (encoded by the adhE gene) physiologically catalyzes the sequential reduction of acetyl-CoA to acetaldehyde and then to ethanol under fermentative conditions. The NH(2)-terminal region of the AdhE protein is highly homologous to aldehyde:NAD(+) oxidoreductases, whereas the COOH-terminal region is homologous to a family of Fe(2+)-dependent ethanol:NAD(+) oxidoreductases. This fusion protein also functions as a pyruvate formate lyase deactivase. E. coli cannot grow aerobically on ethanol as the sole carbon and energy source because of inadequate rate of adhE transcription and the vulnerability of the AdhE protein to metal-catalyzed oxidation. In this study, we characterized 16 independent two-step mutants with acquired and improved aerobic growth ability on ethanol. The AdhE proteins in these mutants catalyzed the sequential oxidation of ethanol to acetaldehyde and to acetyl-CoA. All first stage mutants grew on ethanol with a doubling time of about 240 min. Sequence analysis of a randomly chosen mutant revealed an Ala-267 --> Thr substitution in the acetaldehyde:NAD(+) oxidoreductase domain of AdhE. All second stage mutants grew on ethanol with a doubling time of about 90 min, and all of them produced an AdhE(A267T/E568K). Purified AdhE(A267T) and AdhE(A267T/E568K) showed highly elevated acetaldehyde dehydrogenase activities. It therefore appears that when AdhE catalyzes the two sequential reactions in the counter-physiological direction, acetaldehyde dehydrogenation is the rate-limiting step. Both mutant proteins were more thermosensitive than the wild-type protein, but AdhE(A267T/E568K) was more thermal stable than AdhE(A267T). Since both mutant enzymes exhibited similar kinetic properties, the second mutation probably conferred an increased growth rate on ethanol by stabilizing AdhE(A267T).

Regulation of expression of the adhE gene, encoding ethanol oxidoreductase in Escherichia coli: transcription from a downstream promoter and regulation by fnr and RpoS

The adhE gene of Escherichia coli, located at min 27 on the chromosome, encodes the bifunctional NAD-linked oxidoreductase responsible for the conversion of acetyl-coenzyme A to ethanol during fermentative growth. The expression of adhE is dependent on both transcriptional and posttranscriptional controls and is about 10-fold higher during anaerobic than during aerobic growth. Two putative transcriptional start sites have been reported: one at position -292 and the other at -188 from the translational start codon ATG. In this study we show, by using several different transcriptional and translational fusions to the lacZ gene, that both putative transcriptional start sites can be functional and each site can be redox regulated. Although both start sites are NarL repressible in the presence of nitrate, Fnr activates only the -188 start site and Fis is required for the transcription of only the -292 start site. In addition, it was discovered that RpoS activates adhE transcription at both start sites. Under all experimental conditions tested, however, only the upstream start site is active. Available evidence indicates that under those conditions, the upstream promoter region acts as a silencer of the downstream transcriptional start site. Translation of the mRNA starting at -292, but not the one starting at -188, requires RNase III. The results support the previously postulated ribosomal binding site (RBS) occlusion model, according to which RNase III cleavage is required to release the RBS from a stem-loop structure in the long transcript.

Regulation of adhE (encoding ethanol oxidoreductase) by the Fis protein in Escherichia coli

The adhE gene of Escherichia coli encodes a multifunctional ethanol oxidoreductase whose expression is 10-fold higher under anaerobic than aerobic conditions. Transcription of the gene is under the negative control of the Cra (catabolite repressor-activator) protein, whereas translation of the adhE mRNA requires processing by RNase III. In this report, we show that the expression of adhE also depends on the Fis (factor for inversion stimulation) protein. A strain bearing a fis::kan null allele failed to grow anaerobically on glucose solely because of inadequate adhE transcription. However, fis expression itself is not under redox control. Sequence inspection of the adhE promoter revealed three potential Fis binding sites. Electrophoretic mobility shift analysis, using purified Fis protein and adhE promoter DNA, showed three different complexes.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Cloning of the Lactococcus lactis adhE gene, encoding a multifunctional alcohol dehydrogenase, by complementation of a fermentative mutant of Escherichia coli

The Lactococcus lactis adhE gene, which encodes a multifunctional alcohol dehydrogenase, has been cloned and characterized. A DNA fragment encoding the putative alcohol dehydrogenase domain of the AdhE protein was cloned by screening an L. lactis genomic library in a fermentative mutant of Escherichia coli and selecting for the ability to grow anaerobically. Further analysis of the clone obtained allowed the cloning of the entire adhE gene sequence. Analysis of adhE expression in L. lactis during anaerobiosis showed induction at the transcriptional level, especially in medium containing glucose. Constructed mutant strains produced reduced amounts of ethanol under anaerobic conditions. With the L. lactis gene as a probe, adhE homologs were found in other industrially relevant lactic acid bacteria.

Regulation of expression of the ethanol dehydrogenase gene (adhE) in Escherichia coli by catabolite repressor activator protein Cra

The adhE gene encodes ethanol dehydrogenase and is located at min 27.9 of the Escherichia coli chromosome. Expression of adhE is about 10-fold higher in cells grown anaerobically than in cells grown aerobically and is dependent on both transcriptional and posttranscriptional factors. In this study, a trans-regulatory element repressing adhE expression was characterized by genetic and biochemical approaches. A mutation downregulating adhE expression was mapped at min 2 of the chromosome. DNA sequence analysis revealed a missense mutation in the cra gene, formerly known as fruR. The cra gene encodes a catabolite repressor-activator protein (Cra) involved in the modulation of carbon flow in E. coli. The mutant protein (Cra*) sustained an Arg148-->His substitution causing 1.5- and 3-fold stronger repression of adhE transcription under anaerobic and aerobic conditions, respectively. By contrast, cra null mutants displayed 1.5- and 4-fold increased adhE transcription under those conditions. Disruption of the cra gene did not abolish the anaerobic activation of the adhE gene but diminished it twofold. Cra and Cra* were purified as fusion proteins tagged with an N-terminal 6xHis element. In vitro, both fusion proteins showed binding to the adhE promoter region and to the control fruB promoter region, which is a known Cra target. However, only 6xHis-tagged Cra, and not 6xHis-Cra*, was displaced from the DNA target by the effector, fructose-1-phosphate (F1P), suggesting that the mutant protein is locked in a promoter-binding conformation and is no longer responsive to F1P. We suggest that Cra helps to tighten the control of adhE transcription under aerobic conditions by its repression.

Translation of the adhE transcript to produce ethanol dehydrogenase requires RNase III cleavage in Escherichia coli

Previous studies have shown that the adhE gene, which encodes a multifunctional protein with ethanol dehydrogenase activity, is under transcriptional regulation. The level of dehydrogenase activity in cells grown fermentatively is about 10-fold higher than that in cells grown aerobically. In these studies, we mapped the promoter to a region well upstream of the protein-coding region of adhE. Unexpectedly, in mutants lacking the endoribonuclease RNase III, no significant ethanol dehydrogenase activity was detected in cells grown anaerobically on rich (Luria-Bertani) medium supplemented with glucose, even though adhE mRNA levels were high. Indeed, like Delta adhE mutants, strains lacking RNase III failed to grow fermentatively on glucose but grew on the more oxidized carbon source glucuronate. Computer-generated secondary structures of the putative 5' untranslated region of adhE mRNA suggest that the ribosome binding site is occluded by intramolecular base pairing. It seems likely that cleavage of this secondary structure by RNase III is necessary for efficient translation initiation.

Identification of the transcriptional activator controlling the butanediol fermentation pathway in Klebsiella terrigena

The gene budR, whose product is responsible for induction of the butanediol formation pathway under fermentative growth conditions in Klebsiella terrigena, has been cloned and sequenced. This gene is separated from the budABC operon by a nontranslated region of 106 bp and transcribed in the opposite direction. budR codes for a protein of molecular weight 32,124, the sequence of which exhibits characteristics of regulators belonging to the LysR family. When transferred into the heterologous host Escherichia coli, budR activates expression of budA'-lacZ transcriptional and translational fusions with a regulatory pattern identical to that in K. terrigena, namely, induction by acetate, low pH, and anaerobiosis. Induction by acetate was specific, indicating that it is the physiological inducer. Primer extension analysis located the start site of transcription to two positions, 23 and 24 bp upstream of the budR initiation codon, and also showed that BudR strongly autoregulates its own expression. The products of fhlA, arcA, hip, ntrA, and katF did not influence expression of the bud operon. A mutation in fnr, however, led to a threefold increase in expression, indicating that Fnr acts as a repressor. The results support the notion that BudR coordinates the activity of the energy-conserving, nonreductive, but acidifying acetate formation pathway with the expression of the non-energy-conserving, reductive, but nonacidifying butanediol pathway.

Metabolic pathway for biosynthesis of poly(3-hydroxybutyrate-co-4-hydroxybutyrate) from 4-hydroxybutyrate by Alcaligenes eutrophus

Various aerobic Gram-negative bacteria have been examined for their ability to use 4-hydroxybutyrate and 1,4-butanediol as carbon source for growth. Alcaligenes eutrophus strains H16, HF39, PHB-4 and Pseudomonas denitrificans 'Morris' were not able to grow with 1,4-butanediol or 4-hydroxybutyrate. From A. eutrophus HF39 spontaneous primary mutants (e.g. SK4040) were isolated which grew on 4-hydroxybutyrate with doubling times of approximately 3 h. Tn5::mob mutagenesis of mutant SK4040 led to the isolation of two phenotypically different classes of secondary mutants which were affected in the utilization of 4-hydroxybutyrate. Mutants exhibiting the phenotype 4-hydroxybutyrate-negative did not grow with 4-hydroxybutyrate, and mutants exhibiting the phenotype 4-hydroxybutyrate-leaky grew at a significantly lower rate with 4-hydroxybutyrate. Hybridization experiments led to the identification of a 10-kbp genomic EcoRI fragment of A. eutrophus SK4040, which was altered in mutants with the phenotype 4-hydroxybutyrate-negative, and of two 1-kbp and 4.5-kbp genomic EcoRI fragments, which were altered in mutants with the phenotype 4-hydroxybutyrate-leaky. This 10-kbp EcoRI fragment was cloned from A. eutrophus SK4040, and conjugative transfer of a pVDZ'2 hybrid plasmid to A. eutrophus H16 conferred the ability to grow with 4-hydroxybutyrate to the wild type. DNA-sequence analysis of this fragment, enzymic analysis of the wild type and of mutants of A. eutrophus as well as of recombinant strains of Escherichia coli led to the identification of a structural gene encoding for a 4-hydroxybutyrate dehydrogenase which was affected by transposon mutagenesis in five of six available 4-hydroxybutyrate-negative mutants. Enzymic studies also provided evidence for the presence of an active succinate-semialdehyde dehydrogenase in 4-hydroxybutyrate-grown cells. This indicated that degradation of 4-hydroxybutyrate occurs via succinate semialdehyde and succinate and that the latter is degraded by the citric acid cycle. NMR studies of poly(3-hydroxybutyrate-co-4-hydroxybutyrate) accumulated from 4-hydroxy [1-13C]butyrate or 4-hydroxy[2-13C]butyrate as substrate gave no evidence for a direct conversion of 4-hydroxybutyrate into 3-hydroxybutyrate and therefore supported the results of enzymic analysis.

Nitrate regulation of anaerobic respiratory gene expression in Escherichia coli

Synthesis of most anaerobic respiratory pathways is subject to dual regulation by anaerobiosis and nitrate. Anaerobic induction is mediated by the FNR protein. Dual interacting two-component regulatory systems mediate nitrate induction and repression. The response regulator protein NARL binds DNA to control nitrate induction and repression of genes encoding nitrate respiration enzymes and alternate anaerobic respiratory enzymes, respectively. The homologous protein NARP controls nitrite induction of at least two operons. Nitrate and nitrite signalling are both mediated by the homologous sensor proteins NARX and NARQ. Recent mutational analyses have defined a heptamer sequence necessary for specific DNA binding by the NARL protein. These heptamers are located at different positions in the control regions of different operons. The NARL protein-binding sites in the narG (nitrate reductase) and narK (nitrate-nitrite antiporter) operon control regions are located approximately 200bp upstream of the transcription initiation site. The integration host factor (IHF) greatly stimulates nitrate induction of these operons, indicating that a specific DNA loop brings NARL protein, bound at the upstream region, into the proximity of the promoter for transcription activation. Other NARL protein-dependent opersons do not require IHF for nitrate induction, and the arrangement of NARL heptamer sequences in these control regions is quite different. This complexity of signal transduction pathways, coupled with the diversity of control region architecture, combine to provide many interesting areas for future investigation. An additional challenge is to determine how or if the FNR and NARL proteins interact to mediate dual positive control of transcription initiation.

Adaptation of Escherichia coli to redox environments by gene expression

Escherichia coli is adroit in exploiting environmental energy sources to its greatest profit. A key strategy is to channel electron transport from donor to a terminal acceptor(s) so that the voltage drop is maximal. At the level of transcription, the goal is achieved by the interaction of three global regulatory systems, Fnr, NarL/NarX and ArcB/ArcA. In addition, the regulator FhlA is involved in a cascade-controlled pathway for the formate branch of the pyruvate fermentation pathway.

Anaerobic regulation of the adhE gene, encoding the fermentative alcohol dehydrogenase of Escherichia coli

The regulation of the adhE gene, which encodes the trifunctional fermentative acetaldehyde-alcohol dehydrogenase of Escherichia coli, was investigated by the construction of gene fusions and by two-dimensional protein gel electrophoresis. Both operon and protein fusions of adhE to lacZ were induced 10- to 20-fold by anaerobic conditions, and both fusions were repressed by nitrate, demonstrating that regulation is at the level of transcription. Nitrate repression of phi (adhE-lacZ) expression, as well as of alcohol dehydrogenase enzyme activity, was partly relieved by a mutation in narL. Mutations in rpoN or fnr had no effect on the expression of adhE. Two-dimensional protein gels demonstrated that increases in the amount of adhE protein correlated with increases in enzyme activity, demonstrating that induction was due to synthesis of new protein, not to activation of preexisting protein. When oxidized sugar derivatives such as gluconate or glucuronate were used as carbon sources, the anaerobic expression of phi (adhE-lacZ) was greatly reduced, whereas when sugar alcohols such as sorbitol were used, the expression was increased compared with expression when glucose was the carbon source. This observation suggested that induction of phi (adhE-lacZ) might depend on the level of reduced NADH, which should be highest with sorbitol-grown cells and lowest with glucuronate-grown cells. When phi (adhE-lacZ) was present in a strain deleted for the adhE structural gene, anaerobic expression of phi (adhE-lacZ) was approximately 10-fold higher than in an adhE+ strain. Since the presence of alcohol dehydrogenase would serve to decrease NADH levels, this finding again implies that the adhE gene is regulated by the concentration of reduced NAD. Introduction of a pgi (phosphoglucose isomerase) mutation reduced the anaerobic induction of phi(adhE-lacZ) when the cells were grown on glucose, but had little effect on fructose-grown cells. Pyruvate did not overcome the pgi effect, but glycerol 3-phosphate did, which is again consistent with the possibility that adhE expression responds to the level of reduced NAD rather than to a glycolytic intermediate.

Identification and characterization of narQ, a second nitrate sensor for nitrate-dependent gene regulation in Escherichia coli

In response to nitrate availability, Escherichia coli regulates the synthesis of a number of enzymes involved in anaerobic respiration and fermentation. When nitrate is present, nitrate reductase (narGHJI) gene expression is induced, while expression of the DMSO/TMAO reductase (dmsABC), fumarate reductase (frdABCD) and fermentation related genes are repressed. The narL and narX gene products are required for this nitrate-dependent control, and apparently function as members of a two-component regulatory system. NarX is a presumed sensor-transmitter for nitrate and possibly molybdenum detection. The presumed response-regulator, NarL, when activated by NarX then binds at the regulatory DNA sites of genes to modulate their expression. In this study a third nitrate regulatory gene, narQ, was identified that also participates in nitrate-dependent gene regulation. Strains defective in either narQ or narX alone exhibited no nitrate-dependent phenotype whereas mutants defective in both narQ and narX were fully inactive for nitrate-dependent repression or activation. In all conditions tested, this regulation required a functional narL gene product. These findings suggest that the narX and narQ products have complementary sensor-transmitter functions for nitrate detection, and can work independently to activate NarL, for eliciting nitrate-dependent regulation of anaerobic electron transport and fermentation functions. The narQ gene was cloned, sequenced, and compared with the narX gene. Both gene products are similar in size, hydrophobicity, and sequence, and contain a highly conserved histidine residue common to sensor-transmitter proteins.