Integration host factor is required for anaerobic pyruvate induction of pfl operon expression in Escherichia coli

The formate-hydrogen axis and its impact on the physiology of enterobacterial fermentation

Formic acid (HCOOH) and dihydrogen (H2) are characteristic products of enterobacterial mixed-acid fermentation, with H2 generation increasing in conjunction with a decrease in extracellular pH. Formate and acetyl-CoA are generated by radical-based and coenzyme A-dependent cleavage of pyruvate catalysed by pyruvate formate-lyase (PflB). Formate is also the source of H2, which is generated along with carbon dioxide through the action of the membrane-associated, cytoplasmically-oriented formate hydrogenlyase (FHL-1) complex. Synthesis of the FHL-1 complex is completely dependent on the cytoplasmic accumulation of formate. Consequently, formate determines its own disproportionation into H2 and CO2 by the FHL-1 complex. Cytoplasmic formate levels are controlled by FocA, a pentameric channel that translocates formic acid/formate bidirectionally between the cytoplasm and periplasm. Each protomer of FocA has a narrow hydrophobic pore through which neutral formic acid can pass. Two conserved amino acid residues, a histidine and a threonine, at the center of the pore control directionality of translocation. The histidine residue is essential for pH-dependent influx of formic acid. Studies with the formate analogue hypophosphite and amino acid variants of FocA suggest that the mechanisms of formic acid efflux and influx differ. Indeed, current data suggest, depending on extracellular formate levels, two separate uptake mechanisms exist, both likely contributing to maintain pH homeostasis. Bidirectional formate/formic acid translocation is dependent on PflB and influx requires an active FHL-1 complex. This review describes the coupling of formate and H2 production in enterobacteria.

Directed strain evolution restructures metabolism for 1-butanol production in minimal media

Engineering a microbial strain for production sometimes entails metabolic modifications that impair essential physiological processes for growth or production. Restoring these functions may require amending a variety of non-obvious physiological networks, and thus, rational design strategies may not be practical. Here we demonstrate that growth and production may be restored by evolution that repairs impaired metabolic function. Furthermore, we use genomics, metabolomics and proteomics to identify several underlying mutations and metabolic perturbations that allow metabolism to repair. Previously, high titers of butanol production were achieved by Escherichia coli using a growth-coupled, modified Clostridial CoA-dependent pathway after all native fermentative pathways were deleted. However, production was only observed in rich media. Native metabolic function of the host was unable to support growth and production in minimal media. We use directed cell evolution to repair this phenotype and observed improved growth, titers and butanol yields. We found a mutation in pcnB which resulted in decreased plasmid copy numbers and pathway enzymes to balance resource utilization. Increased protein abundance was measured for biosynthetic pathways, glycolytic enzymes have increased activity, and adenosyl energy charge was increased. We also found mutations in the ArcAB two-component system and integration host factor (IHF) that tune redox metabolism to alter byproduct formation. These results demonstrate that directed strain evolution can enable systematic adaptations to repair metabolic function and enhance microbial production. Furthermore, these results demonstrate the versatile repair capabilities of cell metabolism and highlight important aspects of cell physiology that are required for production in minimal media.

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.

The bacterial response regulator ArcA uses a diverse binding site architecture to regulate carbon oxidation globally

Despite the importance of maintaining redox homeostasis for cellular viability, how cells control redox balance globally is poorly understood. Here we provide new mechanistic insight into how the balance between reduced and oxidized electron carriers is regulated at the level of gene expression by mapping the regulon of the response regulator ArcA from Escherichia coli, which responds to the quinone/quinol redox couple via its membrane-bound sensor kinase, ArcB. Our genome-wide analysis reveals that ArcA reprograms metabolism under anaerobic conditions such that carbon oxidation pathways that recycle redox carriers via respiration are transcriptionally repressed by ArcA. We propose that this strategy favors use of catabolic pathways that recycle redox carriers via fermentation akin to lactate production in mammalian cells. Unexpectedly, bioinformatic analysis of the sequences bound by ArcA in ChIP-seq revealed that most ArcA binding sites contain additional direct repeat elements beyond the two required for binding an ArcA dimer. DNase I footprinting assays suggest that non-canonical arrangements of cis-regulatory modules dictate both the length and concentration-sensitive occupancy of DNA sites. We propose that this plasticity in ArcA binding site architecture provides both an efficient means of encoding binding sites for ArcA, σ(70)-RNAP and perhaps other transcription factors within the same narrow sequence space and an effective mechanism for global control of carbon metabolism to maintain redox homeostasis.

Coordination of FocA and pyruvate formate-lyase synthesis in Escherichia coli demonstrates preferential translocation of formate over other mixed-acid fermentation products

Enterobacteria such as Escherichia coli generate formate, lactate, acetate, and succinate as major acidic fermentation products. Accumulation of these products in the cytoplasm would lead to uncoupling of the membrane potential, and therefore they must be either metabolized rapidly or exported from the cell. E. coli has three membrane-localized formate dehydrogenases (FDHs) that oxidize formate. Two of these have their respective active sites facing the periplasm, and the other is in the cytoplasm. The bidirectional FocA channel translocates formate across the membrane delivering substrate to these FDHs. FocA synthesis is tightly coupled to synthesis of pyruvate formate-lyase (PflB), which generates formate. In this study, we analyze the consequences on the fermentation product spectrum of altering FocA levels, uncoupling FocA from PflB synthesis or blocking formate metabolism. Changing the focA translation initiation codon from GUG to AUG resulted in a 20-fold increase in FocA during fermentation and an ∼3-fold increase in PflB. Nevertheless, the fermentation product spectrum throughout the growth phase remained similar to that of the wild type. Formate, acetate, and succinate were exported, but only formate was reimported by these cells. Lactate accumulated in the growth medium only in mutants lacking FocA, despite retaining active PflB, or when formate could not be metabolized intracellularly. Together, these results indicate that FocA has a strong preference for formate as a substrate in vivo and not other acidic fermentation products. The tight coupling between FocA and PflB synthesis ensures adequate substrate delivery to the appropriate FDH.

Escherichia coli redox mutants as microbial cell factories for the synthesis of reduced biochemicals

Bioprocesses conducted under conditions with restricted O₂ supply are increasingly exploited for the synthesis of reduced biochemicals using different biocatalysts. The model facultative aerobe Escherichia coli, the microbial cell factory par excellence, has elaborate sensing and signal transduction mechanisms that respond to the availability of electron acceptors and alternative carbon sources in the surrounding environment. In particular, the ArcBA and CreBC two-component signal transduction systems are largely responsible for the metabolic regulation of redox control in response to O₂ availability and carbon source utilization, respectively. Significant advances in the understanding of the biochemical, genetic, and physiological duties of these regulatory systems have been achieved in recent years. This situation allowed to rationally-design novel engineering approaches that ensure optimal carbon and energy flows within central metabolism, as well as to manipulate redox homeostasis, in order to optimize the production of industrially-relevant metabolites. In particular, metabolic flux analysis provided new clues to understand the metabolic regulation mediated by the ArcBA and CreBC systems. Genetic manipulation of these regulators proved useful for designing microbial cells factories tailored for the synthesis of reduced biochemicals with added value, such as poly(3-hydroxybutyrate), under conditions with restricted O₂ supply. This network-wide strategy is in contrast with traditional metabolic engineering approaches, that entail direct modification of the pathway(s) at stake, and opens new avenues for the targeted modulation of central catabolic pathways at the transcriptional level.

Pyruvate catabolism and hydrogen synthesis pathway genes of Clostridium thermocellum ATCC 27405

Clostridium thermocellum is a gram-positive, acetogenic, thermophilic, anaerobic bacterium that degrades cellulose and carries out mixed product fermentation, catabolising cellulose to acetate, lactate, and ethanol under various growth conditions, with the concomitant release of H(2) and CO(2). Very little is known about the factors that determine metabolic fluxes influencing H(2) synthesis in anaerobic, cellulolytic bacteria like C. thermocellum. We have begun to investigate the relationships between genome content, gene expression, and end-product synthesis in C. thermocellum cultured under different conditions. Using bioinformatics tools and the complete C. thermocellum 27405 genome sequence, we identified genes encoding key enzymes in pyruvate catabolism and H(2)-synthesis pathways, and have confirmed transcription of these genes throughout growth on α-cellulose by reverse transcriptase polymerase chain reaction. Bioinformatic analyses revealed two putative lactate dehydrogenases, one pyruvate formate lyase, four pyruvate:formate lyase activating enzymes, and at least three putative pyruvate:ferredoxin oxidoreductase (POR) or POR-like enzymes. Our data suggests that hydrogen may be generated through the action of either a Ferredoxin (Fd)-dependent NiFe hydrogenase, often referred to as "Energy-converting Hydrogenases", or via NAD(P)Hdependent Fe-only hydrogenases which would permit H(2) production from NADH generated during the glyceraldehyde-3-phosphate dehydrogenase reaction. Furthermore, our findings show the presence of a gene cluster putatively encoding a membrane integral NADH:Fd oxidoreductase, suggesting a possible mechanism in which electrons could be transferred between NADH and ferredoxin. The elucidation of pyruvate catabolism pathways and mechanisms of H(2) synthesis is the first step in developing strategies to increase hydrogen yields from biomass. Our studies have outlined the likely pathways leading to hydrogen synthesis in C. thermocellum strain 27405, but the actual functional roles of these gene products during pyruvate catabolism and in H 2 synthesis remain to be elucidated, and will need to be confirmed using both expression analysis and protein characterization.

Contributions of [4Fe-4S]-FNR and integration host factor to fnr transcriptional regulation

Maintaining appropriate levels of the global regulator FNR is critical to its function as an O(2) sensor. In this study, we examined the mechanisms that control transcription of fnr to increase our understanding of how FNR protein levels are regulated. Under anaerobic conditions, one mechanism that controls fnr expression is negative autoregulation by the active [4Fe-4S] form of FNR. Through DNase I footprinting and in vitro transcription experiments, we observed that direct binding of [4Fe-4S]-FNR to the predicted downstream FNR binding site is sufficient for repression of the fnr promoter in vitro. In addition, the downstream FNR binding site was required for repression of transcription from fnr'-lacZ fusions in vivo. No repression of fnr was observed in vivo or in vitro with the apoprotein form of FNR, indicating that repression requires the dimeric, Fe-S cluster-containing protein. Furthermore, our in vitro and in vivo data suggest that [4Fe-4S]-FNR does not bind to the predicted upstream FNR binding site within the fnr promoter. Rather, we provide evidence that integration host factor binds to this upstream region and increases in vivo expression of Pfnr under both aerobic and anaerobic conditions.

Formate synthesis by Clostridium thermocellum during anaerobic fermentation

We have detected formate synthesis by Clostridium thermocellum 27405 cultured in both cellobiose and alpha-cellulose. While formate synthesis has been reported for one strain of C. thermocellum (strain I-1-B), numerous studies of C. thermocellum 27405 fermentation, conducted under different growth conditions, failed to detect the presence of formate. Thus, the status of formate synthesis as a fermentation end product by C. thermocellum has been uncertain. Formate synthesis competes with the synthesis of hydrogen (H2) as a fermentation end product, and thus would negatively impact H2 yields in processes designed to generate H2 from biomass. Understanding the mechanism of formate synthesis is the first step in devising means of mitigating its production. Transcription of putative pfl, fnr, and adhE genes, encoding pyruvate formate-lyase (PFL), PFL-activating enzyme (PFL-AE), and alcohol dehydrogenase E (ADH-E) enzymes, respectively, were detected by reverse transcriptase polymerase chain reactions using total RNA extracted from stationary phase C. thermocellum cultured on cellobiose. The PCR products observed correspond to the expected amplicon sizes. Nucleotide sequence analysis of the cloned PCR products followed by BLAST analyses confirmed their identity. Formate production was detected throughout growth, and PFL enzyme activity was detected in late log and stationary phase (OD600 = 0.7 and 0.9, respectively) in extracts of C. thermocellum cultured on cellobiose. BLAST analyses revealed that C. thermocellum PFL and PFL-AE have greater amino acid sequence identity with equivalent enzymes from Bacillus and Thermocynechococcus species than with other Clostridium species, but C. thermocellum ADH-E has greater amino acid sequence identity with Clostridium species.

Indirect recognition in sequence-specific DNA binding by Escherichia coli integration host factor: the role of DNA deformation energy

Integration host factor (IHF) is a bacterial histone-like protein whose primary biological role is to condense the bacterial nucleoid and to constrain DNA supercoils. It does so by binding in a sequence-independent manner throughout the genome. However, unlike other structurally related bacterial histone-like proteins, IHF has evolved a sequence-dependent, high affinity DNA-binding motif. The high affinity binding sites are important for the regulation of a wide range of cellular processes. A remarkable feature of IHF is that it employs an indirect readout mechanism to bind and wrap DNA at both the nonspecific and high affinity (sequence-dependent) DNA sites. In this study we assessed the contributions of pre-formed and protein-induced DNA conformations to the energetics of IHF binding. Binding energies determined experimentally were compared with energies predicted for the IHF-induced deformation of the DNA helix (DNA deformation energy) in the IHF-DNA complex. Combinatorial sets of de novo DNA sequences were designed to systematically evaluate the influence of sequence-dependent structural characteristics of the conserved IHF recognition elements of the consensus DNA sequence. We show that IHF recognizes pre-formed conformational characteristics of the consensus DNA sequence at high affinity sites, whereas at all other sites relative affinity is determined by the deformational energy required for nearest-neighbor base pairs to adopt the DNA structure of the bound DNA-IHF complex.

Evidence for novel processing of the anaerobically inducible dicistronic focA-pfl mRNA transcript in Escherichia coli

The anaerobically inducible dicistronic focA-pfl operon is transcribed from three co-ordinately regulated promoters that are located 5' of the operon. Remarkably, the 5' ends of four further highly abundant operon-internal transcripts are located within the focA gene, with a fifth transcript mapping in the intergenic region between focA and pfl. The findings of this study demonstrate that the bulk of these five operon-internal transcripts are the result of processing. Processing was independent of the broad-spectrum endoribonucleases associated with mRNA turnover and still occurred when the upstream regulatory region of the operon was replaced with two different heterologous promoters recognized by Escherichia coli core RNA polymerase, including the tetP promoter. However, when the T7Phi10 promoter was introduced upstream of the focA-pfl operon, mainly full-length transcript and a minor amount of two processing products were observed. T7 RNA polymerase mutants that exhibit reduced elongation speed did not restore the wild-type transcript-processing pattern. Moreover, processing was independent of focA translation. Taken together, these data suggest that processing of the focA-pfl transcripts occurs by a novel mechanism that might require the action of E. coli core RNA polymerase.

Expression of fnr is constrained by an upstream IS5 insertion in certain Escherichia coli K-12 strains

FNR is a global transcriptional regulator that controls anaerobic gene expression in Escherichia coli. Through the use of a number of approaches it was shown that fnr gene expression is reduced approximately three- to fourfold in E. coli strain MC4100 compared with the results seen with strain MG1655. This reduction in fnr expression is due to the insertion of IS5 (is5F) in the regulatory region of the gene at position -41 relative to the transcription initiation site. Transcription of the fnr gene nevertheless occurs from its own promoter in strain MC4100, but transcript levels are reduced approximately fourfold compared with those seen with strain MG1655. Remarkably, in strains bearing is5F the presence of Hfq prevents IS5-dependent transcriptional silencing of fnr expression. Thus, an hfq mutant of MC4100 is devoid of FNR protein and has the phenotype of an fnr mutant. In strain MG1655, or a derivative of MC4100 lacking is5F, mutation of hfq had no effect on fnr transcript levels. This finding indicates that IS5 mediates the effect of Hfq on fnr expression in MC4100. Western blot analysis revealed that cellular levels of FNR were reduced threefold in strain MC4100 compared with strain MG1655 results. A selection of FNR-dependent genes fused to lacZ were analyzed for the effects of reduced FNR levels on anaerobic gene expression. Expression of some operons, e.g., focA-pfl and fdnGHJI, was unaffected by reduction in the level of FNR, while the expression of other genes such as ndh and nikA was clearly affected.

Integration host factor is essential for the optimal expression of the styABCD operon in Pseudomonas fluorescens ST

The StyS/StyR two-component regulatory system of Pseudomonas fluorescens ST controls the expression of the styABCD operon coding for the styrene degradation upper pathway. In a previous work we showed that the promoter of the catabolic operon (PstyA) is induced by styrene and repressed to differing extents by organic acids or carbohydrates. In order to study the mechanisms controlling the expression of this operon, we performed a functional analysis on 5' deletions of PstyA by the use of a promoter-probe system. These studies demonstrated that a palindromic region (sty box), located from nucleotides -52 to -37 with respect to the transcriptional start point is essential for PstyA activity. Moreover, additional regulatory regions involved in the modulation of PstyA activity were found along the promoter sequence. In particular, deletion of a putative StyR binding site, homologous to the 3' half of the sty box and located upstream of this box, resulted in 65% reduction of the induction level of the reporter gene. Additionally, we performed bandshift assays with a DNA probe corresponding to PstyA and protein crude extracts from P. fluorescens ST, using specific DNA fragments as competitors. In these experiments we demonstrated that IHF binds an AT-rich region located upstream of the sty box. On the basis of this finding, coupled with the results obtained with PstyA functional analysis, we suggest that the role of the IHF-mediated DNA bend is to bring closer, in an overlapping position, the upstream StyR putative binding site and the downstream sty box, and that the formed complex enhances transcription.

A novel mechanism controls anaerobic and catabolite regulation of the Escherichia coli tdc operon

The tdc operon is subject to CRP-controlled catabolite repression. Expression of the operon is also induced anaerobically, although this regulation does not rely on direct control by either FNR or ArcA. Recently, the anaerobic expression of the tdc operon was found to be fortuitously induced in the presence of glucose by a heterologous gene isolated from the Gram-positive anaerobe Clostridium butyricum. The gene, termed tcbC, encoded a histone-like protein of 14.5 kDa. Using tdc-lacZ fusions, it was shown that TcbC did not activate tdc expression by functionally replacing any of the operon regulators. In vitro transcription analyses with RNA polymerase and CRP revealed that faithful CRP-dependent transcription initiation occurred only on supercoiled templates. No specific, CRP-dependent transcription initiation was observed on relaxed or linear DNA templates. Surprisingly, purified His-tagged TcbC activated transcription from a relaxed, circular template, but not from supercoiled or linear templates. Examination of the CRP binding site of the tdc promoter revealed that it was located 43.5 bp upstream of the transcription initiation site. Repositioning of the CRP site at -41.5 bp abolished activation by the TcbC protein and allowed CRP-dependent transcription to occur on linear, relaxed and supercoiled templates. TcbC bound DNA non-specifically; however, in topoisomerase I relaxation assays, it was demonstrated that TcbC imposed torsional constraints on negatively supercoiled DNA, which influenced the ability of the enzyme to relax the topoisomers. Taken together, these results strongly suggest that TcbC activates transcription of tdc by altering the local topological status of the tdc promoter and that, in the wild-type tdc promoter, the CRP binding site is misaligned to allow transcription to occur only under optimal conditions. Indeed, in vivo transcription analyses revealed that repositioning of the CRP binding site to -41.5 bp resulted in high-level, CRP-dependent transcription, even under catabolite-repressing conditions, and that transcription was no longer influenced by TcbC. Remarkably, however, anaerobic regulation of the mutant promoter was retained. This indicates that the other tdc regulators, TdcA and TdcR, govern anaerobic transcription activation by CRP.

An Lrp-like transcriptional regulator from the archaeon Pyrococcus furiosus is negatively autoregulated

The archaeal transcriptional initiation machinery closely resembles core elements of the eukaryal polymerase II system. However, apart from the established basal archaeal transcription system, little is known about the modulation of gene expression in archaea. At present, no obvious eukaryal-like transcriptional regulators have been identified in archaea. Instead, we have previously isolated an archaeal gene, the Pyrococcus furiosus lrpA, that potentially encodes a bacterial-like transcriptional regulator. In the present study, we have for the first time addressed the actual involvement of an archaeal Lrp homologue in transcription modulation. For that purpose, we have produced LrpA in Escherichia coli. In a cell-free P. furiosus transcription system we used wild-type and mutated lrpA promoter fragments to demonstrate that the purified LrpA negatively regulates its own transcription. In addition, gel retardation analyses revealed a single protein-DNA complex, in which LrpA appeared to be present in (at least) a tetrameric conformation. The location of the LrpA binding site was further identified by DNaseI and hydroxyl radical footprinting, indicating that LrpA binds to a 46-base pair sequence that overlaps the transcriptional start site of its own promoter. The molecular basis of the transcription inhibition by LrpA is discussed.

RegulonDB (version 3.0): transcriptional regulation and operon organization in Escherichia coli K-12

RegulonDB is a database on transcription regulation and operon organization in Escherichia coli. The current version describes regulatory signals of transcription initiation, promoters, regulatory binding sites of specific regulators, ribosome binding sites and terminators, as well as information on genes clustered in operons. These specific annotations have been gathered from a constant search in the literature, as well as based on computational sequence predictions. The genomic coordinates of all these objects in the E.coli K-12 chromosome are clearly indicated. Every known object has a link to at least one MEDLINE reference. We have also added direct links to recent expression data of E.coli K-12. The version presented here has important modifications both in the structure of the database, as well as in the amount and type of information encoded in the database. RegulonDB can be accessed on the web at URL: http://www.cifn.unam. mx/Computational_Biology/regulondb/

The Escherichia coli ssuEADCB gene cluster is required for the utilization of sulfur from aliphatic sulfonates and is regulated by the transcriptional activator Cbl

The growth properties of an Escherichia coli strain carrying a chromosomal deletion of the ssuEADCB genes (formerly designated ycbPONME) indicated that the products of this gene cluster are required for the utilization of sulfur from aliphatic sulfonates. Sequence similarity searches indicated that the proteins encoded by ssuA, ssuB, and ssuC are likely to constitute an ABC type transport system, whereas ssuD and ssuE encode an FMNH(2)-dependent monooxygenase and an NAD(P)H-dependent FMN reductase, respectively (Eichhorn, E., van der Ploeg, J. R., and Leisinger, T. (1999) J. Biol. Chem. 274, 26639-26646). Synthesis of beta-galactosidase from a transcriptional chromosomal ssuE'-lacZ fusion was repressed by sulfate or cystine and depended on the presence of a functional cbl gene, which encodes a LysR-type transcriptional regulator. Electrophoretic mobility shift assays with the ssu promoter region and measurements of beta-galactosidase from plasmid-encoded ssuE'-'lacZ fusions showed that full expression of the ssu operon required the presence of a Cbl-binding site upstream of the -35 region. CysB, the LysR transcriptional regulator for the cys genes, was not required for expression of a chromosomal ssuE'-lacZ fusion although the ssu promoter region contained three CysB-binding sites. Integration host factor could also occupy three binding sites in the ssu promoter region but had no influence on expression of a chromosomal ssuE'-lacZ fusion.

Selected phenotypes of ihf mutants of Escherichia coli

In attempts to identify subunit-specific phenotypes of ihf mutants we analyzed viability, thermoresistance and protein synthesis patterns in ihfA and ihfB mutants and their respective parental strains. Despite some detected differences in the two-dimensional protein patterns, no significant subunit-specific, physiological effects could be observed. Each mutant was less viable and less thermoresistant than the wild type strain. Moreover, in contrast to the wild type the mutants did not reduce global protein synthesis after prolonged culturing. Examination of expression of transcriptional fusions allowed us to demonstrate autoregulation of both genes by IHF. Additional IHF binding sites in the regulatory region of both ihf genes were footprinted.

Overlapping promoters modulate Fnr- and ArcA-dependent anaerobic transcriptional activation of the focApfl operon in Escherichia coli

The recently identified P6A promoter of the anaerobically inducible focApfl operon of Escherichia coll overlaps the Fnr (fumarate-nitrate reduction regulator)-dependent P6 promoter. The Fnr-binding site of P6 and the -35 hexamer sequence of P6A are shared between the promoters. Inactivation of P6A, through introduction of a -10 hexamer mutation, resulted in enhanced anaerobic induction of operon expression. The dependence on the ArcA (aerobic respiration control regulator) and Fnr transcription factors for anaerobic induction was tested for several focA-lacZ and pfl-lacZ gene fusions. Anaerobic induction became more dependent on Fnr in derivatives lacking a functional P6A promoter compared with wild-type constructs. Moreover, aerobic expression of the focA gene was reduced by the p6A mutation, as was the dependence on ArcA for anaerobic induction. Inactivation of P6 severely reduced Fnr-dependent anaerobic induction, in accord with previous findings. Transcription analyses demonstrated that a mutation in the -10 hexamer sequence of either P6A or P6 did not adversely affect transcription from the remaining promoter. Taken together, these results indicate that the P6A promoter moderates the Fnr-dependent activation of P6 through competition for RNA polymerase binding.

Promoter 7 of the Escherichia coli pfl operon is a major determinant in the anaerobic regulation of expression by ArcA

The anaerobically inducible pfl operon of Escherichia coli has a regulatory sequence comprising 494 bp, which includes two anaerobically regulated promoters, termed P6 and P7. In this study, we show that in its normal context the activity of P7 is constrained and that one important function of the promoter is to mediate controlled ArcA-dependent regulation of the operon.

Nitrate repression of the Escherichia coli pfl operon is mediated by the dual sensors NarQ and NarX and the dual regulators NarL and NarP

The pfl operon is expressed at high levels anaerobically. Growth of Escherichia coli in the presence of nitrate or nitrite led to a 45% decrease in expression when cells were cultivated in rich medium. Nitrate repression, however, was significantly enhanced (sevenfold) when the cells were cultured in minimal medium. Regulation of pfl expression by nitrate was dependent on the NarL, NarP, NarQ, and NarX proteins but independent of FNR, ArcA, and integration host factor, which are additional regulators of pfl expression. Strains unable to synthesize any one of the NarL, NarP, NarQ, or NarX proteins, but retaining the capacity to synthesize the remaining three, exhibited essentially normal nitrate regulation. In contrast, narL narP and narX narQ double null mutants were devoid of nitrate regulation when cultured in rich medium but they retained some nitrate repression (1.3-fold) when grown in minimal medium. By using lacZ fusions, it was possible to localize the DNA sequences required to mediate nitrate repression to the pfl promoter-regulatory region. DNase I footprinting studies identified five potential binding sites for the wild-type NarL protein in the pfl promoter-regulatory region. Specific footprints were obtained only when NarL was phosphorylated with acetyl phosphate before the binding reaction was performed. Each of the protected regions contained at least one heptamer sequence which has been deduced from mutagenesis studies to be essential for NarL binding (K. Tyson, A. Bell, J. Cole, and S. Busby, Mol. Microbiol. 7:151-157, 1993).

Transcriptional regulation of the proton translocating NADH dehydrogenase genes (nuoA-N) of Escherichia coli by electron acceptors, electron donors and gene regulators

The promoter region and transcriptional regulation of the nuoA-N gene locus encoding the proton-translocating NADH:quinone oxidoreductase was analysed. A 560 bp intergenic region upstream of the nuo locus was followed by a gene (designated lrhA for LysR homologue A) coding for a gene regulator similar to those of the LysR family. Disruption of lrhA did not affect growth (respiratory or non-respiratory) or expression of nuo significantly. Transcriptional regulation of nuo by electron acceptors, electron donors and the transcriptional regulators ArcA, FNR, NarL and NarP, and by IHF (integration host factor) was studied with protein and operon fusions containing the promoter region up to base pair -277 ('nuo277') or up to base pair -89 ('nuo899'). The expression of the nuo277-lacZ fusions was subject to ArcA-mediated anaerobic repression and NarL(+ nitrate)-mediated anaerobic activation. FNR and IHF acted as weak repressors under anaerobic conditions. Expression of nuo899-lacZ was stimulated during anaerobic fumarate respiration and aerobically by C4 dicarboxylates. Therefore, expression of nuo is regulated by O2 and nitrate via ArcA, NarL, FNR and IHF at sites within the -277 region, and by other factors including C4 dicarboxylates at a site between -277 and -899. A physiological role for the transcriptional stimulation by O2 and nitrate is suggested.

Purification of ArcA and analysis of its specific interaction with the pfl promoter-regulatory region

ArcA is one of several transcription factors required for optimal anaerobic induction of the pyruvate formatelyase (pfl) operon. To aid the study at the molecular level of the interaction of ArcA with the pfl promoter-regulatory region we developed a procedure for the isolation of ArcA. The purification of ArcA involved chromatography in heparin agarose, hydroxylapatite and Mono-Q matrices and delivered a protein that was > 95% pure. Gel retardation assays demonstrated that ArcA bound specifically to the pfl regulatory region. Three distinct ArcA-DNA complexes could be resolved depending on the ArcA concentration used. This finding suggested that either multiple ArcA-binding sites are present in the regulatory region or that ArcA can oligomerize at one or more sites. The DNA-binding activity of ArcA could be increased as estimated 10-fold by prior incubation of the protein with carbamoyl phosphate, suggesting that phosphorylation activates DNA binding or oligomerisation. DNase I footprint analyses identified four sites that were protected by ArcA from cleavage. Two of these sites spanned the transcription start site and -10 regions of promoters 6 and 7, while a third site partially overlapped the characterized binding site of integration host factor (IHF). ArcA exhibited the highest affinity for a stretch of DNA located between the IHF site and the transcription start site of promoter 7. These results are congruent with the hypothesis that a higher-order nucleoprotein complex comprising several proteins, including ArcA, is required to activate transcription from the multiple promoters of the pfl operon.

Aerobic-anaerobic gene regulation in Escherichia coli: control by the ArcAB and Fnr regulons

A variety of pathways for carbon and electron flow in the bacterium Escherichia coli and in other enteric bacteria are differentially expressed depending on whether molecular oxygen is present in the cell environment. This review briefly summarizes the metabolic pathways operative during aerobic versus anaerobic cell growth, and provides a regulatory overview for how the cell controls expression of the many genes involved in these processes. The cell has two distinctly different transcriptional regulators, consisting of the Fnr and the ArcA/ArcB regulatory proteins to accomplish this task. Together, they coordinate gene expression to adjust carbon flow with electron flow and energy generation so that cells can balance growth in an efficiently coupled manner.

Pyruvate formate-lyase is not essential for nitrate respiration by Escherichia coli

Defined deletion mutants of Escherichia coli defective for the synthesis of pyruvate formate-lyase (PFL) or pyruvate dehydrogenase (PDH) were analysed in regards their growth in batch culture and their enzyme levels under fermentative and nitrate respiratory conditions. A pfl mutant proved not to be completely auxotrophic for acetate when grown anaerobically in glucose minimal medium. In contrast, a pfl aceEF double mutant exhibited an absolute requirement for acetate, indicating that PDH is the source of acetyl-CoA in the pfl mutant. Growth of both pfl and aceEF single mutants under nitrate respiratory conditions was essentially indistinguishable from the wild-type. Thus, either PFL or PDH can be used to catabolize pyruvate in nitrate-respiring cells. The activities of PFL and PDH measured after growth with nitrate are commensurate with this proposal.

Oxygen regulated gene expression in facultatively anaerobic bacteria

In facultatively anaerobic bacteria such as Escherichia coli, oxygen and other electron acceptors fundamentally influence catabolic and anabolic pathways. E. coli is able to grow aerobically by respiration and in the absence of O2 by anaerobic respiration with nitrate, nitrite, fumarate, dimethylsulfoxide and trimethylamine N-oxide as acceptors or by fermentation. The expression of the various catabolic pathways occurs according to a hierarchy with 3 or 4 levels. Aerobic respiration at the highest level is followed by nitrate respiration (level 2), anaerobic respiration with the other acceptors (level 3) and fermentation. In other bacteria, different regulatory cascades with other underlying principles can be observed. Regulation of anabolism in response to O2 availability is important, too. It is caused by different requirements of cofactors or coenzymes in aerobic and anaerobic metabolism and by the requirement for different O2-independent biosynthetic routes under anoxia. The regulation mainly occurs at the transcriptional level. In E. coli, 4 global regulatory systems are known to be essential for the aerobic/anaerobic switch and the described hierarchy. A two-component sensor/regulator system comprising ArcB (sensor) and ArcA (transcriptional regulator) is responsible for regulation of aerobic metabolism. The FNR protein is a transcriptional sensor-regulator protein which regulates anaerobic respiratory genes in response to O2 availability. The gene activator FhlA regulates fermentative formate and hydrogen metabolism with formate as the inductor. ArcA/B and FNR directly respond to O2, FhlA indirectly by decreased levels of formate in the presence of O2. Regulation of nitrate/nitrite catabolism is effected by two 2-component sensor/regulator systems NarX(Q)/NarL(P) in response to nitrate/nitrite. Co-operation of the different regulatory systems at the target promoters which are in part under dual (or manifold) transcriptional control causes the expression according to the hierarchy. The sensing of the environmental signals by the sensor proteins or domains is not well understood so far. FNR, which acts presumably as a cytoplasmic 'one component' sensor-regulator, is suggested to sense directly cytoplasmic O2-levels corresponding to the environmental O2-levels.

Specific transcriptional requirements for positive regulation of the anaerobically inducible pfl operon by ArcA and FNR

Expression of the pfl operon of Escherichia coli is induced 12- to 15-fold by anaerobiosis and transcription is mediated by seven co-ordinately regulated promoters. The 5' non-translated regulatory region of the operon is approximately 450bp in length and contains two of the seven promoters, termed promoter 6 and promoter 7. Site-directed mutagenesis was used to aid the identification of DNA sequences important in directing transcription from the two promoters and to examine the effects such mutations had on the regulation of anaerobic pfl operon expression. Introduction of chromosomal mutations either in the FNR-binding site or -10 region of promoter 6 blocked transcription from this promoter, as determined by primer extension. Similarly, mutation of the -10 region or the putative FNR half-site located at -50 relative to the transcription start site of promoter 7 severely reduced transcription from that promoter. Prevention of transcription from promoter 6 by the -10 box mutation had no influence on promoter 7 transcription. Surprisingly, however, alteration of the FNR-binding site at promoter 6 did reduce transcription from promoter 7. Thus, a cis mutation located 280 bp downstream on the DNA had a profound effect on promoter 7 transcription. This effect would be commensurate with this mutation disrupting an important interaction between proteins bound at promoter 7 with those bound at promoter 6. Primer extension demonstrated that the promoter 7 mutations had no apparent influence on promoter 6 transcription. By using pfl-lacZ gene fusions it could be shown that the FNR-binding site and -10 region mutations at promoter 6 abolished FNR-dependent anaerobic regulation of pfl operon expression. The equivalent mutations at promoter 7 caused a 25% reduction in anaerobic expression. The residual anaerobic expression in such constructs was FNR-, but no longer ArcA-dependent. A construct in which the -10 region of both promoters 6 and 7 was mutated showed no anaerobic induction of pfl operon expression. This indicates that transcription from both promoters is required for maximal anaerobic regulation by ArcA and FNR.