Regulation of Escherichia coli K-12 hexuronate system genes: exu regulon

A peptidoglycan N-deacetylase specific for anhydroMurNAc chain termini in Agrobacterium tumefaciens

During growth, bacteria remodel and recycle their peptidoglycan (PG). A key family of PG-degrading enzymes is the lytic transglycosylases, which produce anhydromuropeptides, a modification that caps the PG chains and contributes to bacterial virulence. Previously, it was reported that the polar-growing Gram-negative plant pathogen Agrobacterium tumefaciens lacks anhydromuropeptides. Here, we report the identification of an enzyme, MdaA (MurNAc deacetylase A), which specifically removes the acetyl group from anhydromuropeptide chain termini in A. tumefaciens, resolving this apparent anomaly. A. tumefaciens lacking MdaA accumulates canonical anhydromuropeptides, whereas MdaA was able to deacetylate anhydro-N-acetyl muramic acid in purified sacculi that lack this modification. As for other PG deacetylases, MdaA belongs to the CE4 family of carbohydrate esterases but harbors an unusual Cys residue in its active site. MdaA is conserved in other polar-growing bacteria, suggesting a possible link between PG chain terminus deacetylation and polar growth.

Differential Impact of Hexuronate Regulators ExuR and UxuR on the Escherichia coli Proteome

ExuR and UxuR are paralogous proteins belonging to the GntR family of transcriptional regulators. Both are known to control hexuronic acid metabolism in a variety of Gammaproteobacteria but the relative impact of each of them is still unclear. Here, we apply 2D difference electrophoresis followed by mass-spectrometry to characterise the changes in the Escherichia coli proteome in response to a uxuR or exuR deletion. Our data clearly show that the effects are different: deletion of uxuR resulted in strongly enhanced expression of D-mannonate dehydratase UxuA and flagellar protein FliC, and in a reduced amount of outer membrane porin OmpF, while the absence of ExuR did not significantly alter the spectrum of detected proteins. Consequently, the physiological roles of proteins predicted as homologs seem to be far from identical. Effects of uxuR deletion were largely dependent on the cultivation conditions: during growth with glucose, UxuA and FliC were dramatically altered, while during growth with glucuronate, activation of both was not so prominent. During the growth with glucose, maximal activation was detected for FliC. This was further confirmed by expression analysis and physiological tests, thus suggesting the involvement of UxuR in the regulation of bacterial motility and biofilm formation.

Substrate-activated expression of a biosynthetic pathway in Escherichia coli

Microbes can facilitate production of valuable chemicals more sustainably than traditional chemical processes in many cases: they utilize renewable feedstocks, require less energy intensive process conditions, and perform a variety of chemical reactions using endogenous or heterologous enzymes. In response to the metabolic burden imposed by production pathways, chemical inducers are frequently used to initiate gene expression after the cells have reached sufficient density. While chemically inducible promoters are a common research tool used for pathway expression, they introduce a compound extrinsic to the process along with the associated costs. We developed an expression control system for a biosynthetic pathway for the production of d-glyceric acid that utilizes galacturonate as both the inducer and the substrate, thereby eliminating the need for an extrinsic chemical inducer. Activation of expression in response to the feed is actuated by a galacturonate-responsive transcription factor biosensor. We constructed variants of the galacturonate biosensor with a heterologous transcription factor and cognate hybrid promoter, and selected for the best performer through fluorescence characterization. We showed that native E. coli regulatory systems do not interact with our biosensor and favorable biosensor response exists in the presence and absence of galacturonate consumption. We then employed the control circuit to regulate the expression of the heterologous genes of a biosynthetic pathway for the production d-glyceric acid that was previously developed in our lab. Productivity via substrate-induction with our control circuit was comparable to IPTG-controlled induction and significantly outperformed a constitutive expression control, producing 2.13 ± 0.03 g L^-1  d-glyceric acid within 6 h of galacturonate substrate addition. This work demonstrated feed-activated pathway expression to be an attractive control strategy for more readily scalable microbial biosynthesis.

Enzymology of Alternative Carbohydrate Catabolic Pathways

The Embden–Meyerhof–Parnas (EMP) and Entner–Doudoroff (ED) pathways are considered the most abundant catabolic pathways found in microorganisms, and ED enzymes have been shown to also be widespread in cyanobacteria, algae and plants. In a large number of organisms, especially common strains used in molecular biology, these pathways account for the catabolism of glucose. The existence of pathways for other carbohydrates that are relevant to biomass utilization has been recognized as new strains have been characterized among thermophilic bacteria and Archaea that are able to transform simple polysaccharides from biomass to more complex and potentially valuable precursors for industrial microbiology. Many of the variants of the ED pathway have the key dehydratase enzyme involved in the oxidation of sugar derived from different families such as the enolase, IlvD/EDD and xylose-isomerase-like superfamilies. There are the variations in structure of proteins that have the same specificity and generally greater-than-expected substrate promiscuity. Typical biomass lignocellulose has an abundance of xylan, and four different pathways have been described, which include the Weimberg and Dahms pathways initially oxidizing xylose to xylono-gamma-lactone/xylonic acid, as well as the major xylose isomerase pathway. The recent realization that xylan constitutes a large proportion of biomass has generated interest in exploiting the compound for value-added precursors, but few chassis microorganisms can grow on xylose. Arabinose is part of lignocellulose biomass and can be metabolized with similar pathways to xylose, as well as an oxidative pathway. Like enzymes in many non-phosphorylative carbohydrate pathways, enzymes involved in L-arabinose pathways from bacteria and Archaea show metabolic and substrate promiscuity. A similar multiplicity of pathways was observed for other biomass-derived sugars such as L-rhamnose and L-fucose, but D-mannose appears to be distinct in that a non-phosphorylative version of the ED pathway has not been reported. Many bacteria and Archaea are able to grow on mannose but, as with other minor sugars, much of the information has been derived from whole cell studies with additional enzyme proteins being incorporated, and so far, only one synthetic pathway has been described. There appears to be a need for further discovery studies to clarify the general ability of many microorganisms to grow on the rarer sugars, as well as evaluation of the many gene copies displayed by marine bacteria.

Short-Term Adaptation Modulates Anaerobic Metabolic Flux to Succinate by Activating ExuT, a Novel D-Glucose Transporter in Escherichia coli

The sugar phosphotransferase system (PTS) is an essential energy-saving mechanism, particularly under anaerobic conditions. Since the PTS consumes equimolar phosphoenolpyruvate to phosphorylate each molecule of internalized glucose in the process of pyruvate generation, its absence can adversely affect the mixed acid fermentation profile and cell growth under anaerobic conditions. In this study, we report that the ΔptsG mutant cells of Escherichia coli K-12 strain exhibited inefficient glucose utilization, produced a significant amount of succinate, and exhibited a low growth rate. However, cells adapted soon after and started to grow rapidly in the same batch culture. As a result, the adapted ΔptsG cells showed the same mixed acid fermentation profiles as the wild-type cells, which was attributed to the mutation of the mlc gene, a repressor of the D-mannose PTS, another transporter for D-glucose. Similar adaptations were observed in the cells with ΔptsGΔmanX and the cells with ΔptsI that resulted in the production of a substantial amount of succinate and fast growth rate. The genome sequencing showed the presence of null mutations in the exuR gene, which encodes a modulator of exuT-encoded non-PTS sugar transporter, in adapted ΔptsGΔmanX and ΔptsI strains. Results from the RT-qPCR analysis and genetic test confirmed that the enhanced expression of ExuT, a non-PTS sugar transporter, was responsible for the uptake of D-glucose, increased succinate production, and fast growth of adapted cells. In conclusion, our study showed that the regulatory network of sugar transporters can be modulated by short-term adaptation and that downstream metabolic flux could be significantly determined by the choice of sugar transporters.

Single-target regulators form a minor group of transcription factors in Escherichia coli K-12

The identification of regulatory targets of all TFs is critical for understanding the entire network of the genome regulation. The lac regulon of Escherichia coli K-12 W3110 is composed of the lacZYA operon and its repressor lacI gene, and has long been recognized as the seminal model of transcription regulation in bacteria with only one highly preferred target. After the Genomic SELEX screening in vitro of more than 200 transcription factors (TFs) from E. coli K-12, however, we found that most TFs regulate multiple target genes. With respect to the number of regulatory targets, a total of these 200 E. coli TFs form a hierarchy ranging from a single target to as many as 1000 targets. Here we focus a total of 13 single-target TFs, 9 known TFs (BetI, KdpE, LacI, MarR, NanR, RpiR, TorR, UlaR and UxuR) and 4 uncharacterized TFs (YagI, YbaO, YbiH and YeaM), altogether forming only a minor group of TFs in E. coli. These single-target TFs were classified into three groups based on their functional regulation.

Substrate and metabolic promiscuities of d-altronate dehydratase family proteins involved in non-phosphorylative d-arabinose, sugar acid, l-galactose and l-fucose pathways from bacteria

The gene context in microorganism genomes is of considerable help for identifying potential substrates. The C785_RS13685 gene in Herbaspirillum huttiense IAM 15032 is a member of the d-altronate dehydratase protein family, and which functions as a d-arabinonate dehydratase in vitro, is clustered with genes related to putative pentose metabolism. In the present study, further biochemical characterization and gene expression analyses revealed that l-xylonate is a physiological substrate that is ultimately converted to α-ketoglutarate via so-called Route II of a non-phosphorylative pathway. Several hexonates, including d-altronate, d-idonate and l-gluconate, which are also substrates of C785_RS13685, also significantly up-regulated the gene cluster containing C785_RS13685, suggesting a possibility that pyruvate and d- or l-glycerate were ultimately produced (novel Route III). On the contrary, ACAV_RS08155 of Acidovorax avenae ATCC 19860, a homologous gene to C785_RS13685, functioned as a d-altronate dehydratase in a novel l-galactose pathway, through which l-galactonate was epimerized at the C5 position by the sequential activity of two dehydrogenases, resulting in d-altronate. Furthermore, this pathway completely overlapped with Route III of the non-phosphorylative l-fucose pathway. The 'substrate promiscuity' of d-altronate dehydratase protein(s) is significantly expanded to 'metabolic promiscuity' in the d-arabinose, sugar acid, l-fucose and l-galactose pathways.

Characterisation of the First Archaeal Mannonate Dehydratase from Thermoplasma acidophilum and Its Potential Role in the Catabolism of D-Mannose

Mannonate dehydratases catalyse the dehydration reaction from mannonate to 2-keto-3-deoxygluconate as part of the hexuronic acid metabolism in bacteria. Bacterial mannonate dehydratases present in this gene cluster usually belong to the xylose isomerase-like superfamily, which have been the focus of structural, biochemical and physiological studies. Mannonate dehydratases from archaea have not been studied in detail. Here, we identified and characterised the first archaeal mannonate dehydratase (TaManD) from the thermoacidophilic archaeon Thermoplasma acidophilum. The recombinant TaManD enzyme was optimally active at 65 °C and showed high specificity towards D-mannonate and its lactone, D-mannono-1,4-lactone. The gene encoding for TaManD is located adjacent to a previously studied mannose-specific aldohexose dehydrogenase (AldT) in the genome of T. acidophilum. Using nuclear magnetic resonance (NMR) spectroscopy, we showed that the mannose-specific AldT produces the substrates for TaManD, demonstrating the possibility for an oxidative metabolism of mannose in T. acidophilum. Among previously studied mannonate dehydratases, TaManD showed closest homology to enzymes belonging to the xylose isomerase-like superfamily. Genetic analysis revealed that closely related mannonate dehydratases among archaea are not located in a hexuronate gene cluster like in bacteria, but next to putative aldohexose dehydrogenases, implying a different physiological role of mannonate dehydratases in those archaeal species.

Bacillus velezensis FZB42 in 2018: The Gram-Positive Model Strain for Plant Growth Promotion and Biocontrol

Bacillus velezensis FZB42, the model strain for Gram-positive plant-growth-promoting and biocontrol rhizobacteria, has been isolated in 1998 and sequenced in 2007. In order to celebrate these anniversaries, we summarize here the recent knowledge about FZB42. In last 20 years, more than 140 articles devoted to FZB42 have been published. At first, research was mainly focused on antimicrobial compounds, apparently responsible for biocontrol effects against plant pathogens, recent research is increasingly directed to expression of genes involved in bacteria–plant interaction, regulatory small RNAs (sRNAs), and on modification of enzymes involved in synthesis of antimicrobial compounds by processes such as acetylation and malonylation. Till now, 13 gene clusters involved in non-ribosomal and ribosomal synthesis of secondary metabolites with putative antimicrobial action have been identified within the genome of FZB42. These gene clusters cover around 10% of the whole genome. Antimicrobial compounds suppress not only growth of plant pathogenic bacteria and fungi, but could also stimulate induced systemic resistance (ISR) in plants. It has been found that besides secondary metabolites also volatile organic compounds are involved in the biocontrol effect exerted by FZB42 under biotic (plant pathogens) and abiotic stress conditions. In order to facilitate easy access to the genomic data, we have established an integrating data bank ‘AmyloWiki’ containing accumulated information about the genes present in FZB42, available mutant strains, and other aspects of FZB42 research, which is structured similar as the famous SubtiWiki data bank.

A novel pathway for fungal D-glucuronate catabolism contains an L-idonate forming 2-keto-L-gulonate reductase

For the catabolism of D-glucuronate, different pathways are used by different life forms. The pathways in bacteria and animals are established, however, a fungal pathway has not been described. In this communication, we describe an enzyme that is essential for D-glucuronate catabolism in the filamentous fungus Aspergillus niger. The enzyme has an NADH dependent 2-keto-L-gulonate reductase activity forming L-idonate. The deletion of the corresponding gene, the gluC, results in a phenotype of no growth on D-glucuronate. The open reading frame of the A. niger 2-keto-L-gulonate reductase was expressed as an active protein in the yeast Saccharomyces cerevisiae. A histidine tagged protein was purified and it was demonstrated that the enzyme converts 2-keto-L-gulonate to L-idonate and, in the reverse direction, L-idonate to 2-keto-L-gulonate using the NAD(H) as cofactors. Such an L-idonate forming 2-keto-L-gulonate dehydrogenase has not been described previously. In addition, the finding indicates that the catabolic D-glucuronate pathway in A. niger differs fundamentally from the other known D-glucuronate pathways.

Catabolism of Hexuronides, Hexuronates, Aldonates, and Aldarates

Following elucidation of the regulation of the lactose operon in Escherichia coli, studies on the metabolism of many sugars were initiated in the early 1960s. The catabolic pathways of D-gluconate and of the two hexuronates, D-glucuronate and D-galacturonate, were investigated. The post genomic era has renewed interest in the study of these sugar acids and allowed the complete characterization of the D-gluconate pathway and the discovery of the catabolic pathways for L-idonate, D-glucarate, galactarate, and ketogluconates. Among the various sugar acids that are utilized as sole carbon and energy sources to support growth of E. coli, galacturonate, glucuronate, and gluconate were shown to play an important role in the colonization of the mammalian large intestine. In the case of sugar acid degradation, the regulators often mediate negative control and are inactivated by interaction with a specific inducer, which is either the substrate or an intermediate of the catabolism. These regulators coordinate the synthesis of all the proteins involved in the same pathway and, in some cases, exert crosspathway control between related catabolic pathways. This is particularly well illustrated in the case of hexuronide and hexuronate catabolism. The structural genes encoding the different steps of hexuronate catabolism were identified by analysis of numerous mutants affected for growth with galacturonate or glucuronate. E. coli is able to use the diacid sugars D-glucarate and galactarate (an achiral compound) as sole carbon source for growth. Pyruvate and 2-phosphoglycerate are the final products of the D-glucarate/galactarate catabolism.

Novel insights into E. coli's hexuronate metabolism: KduI facilitates the conversion of galacturonate and glucuronate under osmotic stress conditions

Using a gnotobiotic mouse model, we previously observed the upregulation of 2-deoxy-D-gluconate 3-dehydrogenase (KduD) in intestinal E. coli of mice fed a lactose-rich diet and the downregulation of this enzyme and of 5-keto 4-deoxyuronate isomerase (KduI) on a casein-rich diet. The present study aimed to define the role of the so far poorly characterized E. coli proteins KduD and KduI in vitro. Galacturonate and glucuronate induced kduD and kduI gene expression 3-fold and 7 to 11-fold, respectively, under aerobic conditions as well as 9 to 20-fold and 19 to 54-fold, respectively, under anaerobic conditions. KduI facilitated the breakdown of these hexuronates. In E. coli, galacturonate and glucuronate are normally degraded by UxaABC and UxuAB. However, osmotic stress represses the expression of the corresponding genes in an OxyR-dependent manner. When grown in the presence of galacturonate or glucuronate, kduID-deficient E. coli had a 30% to 80% lower maximal cell density and 1.5 to 2-fold longer doubling times under osmotic stress conditions than wild type E. coli. Growth on lactose promoted the intracellular formation of hexuronates, which possibly explain the induction of KduD on a lactose-rich diet. These results indicate a novel function of KduI and KduD in E. coli and demonstrate the crucial influence of osmotic stress on the gene expression of hexuronate degrading enzymes.

Genome sequence of the plant growth promoting strain Bacillus amyloliquefaciens subsp. plantarum B9601-Y2 and expression of mersacidin and other secondary metabolites

The plant-associated Bacillus amyloliquefaciens subsp. plantarum strain B9601-Y2, isolated from wheat rhizosphere, is a powerful plant growth-promoting rhizobacterium. Its relative large genome size of 4.24Mbp, exceeding that of other representatives of the B. amyloliquefaciens subsp. plantarum taxon, is mainly due to the presence of 18 DNA-islands containing remnants of phages, a unique restriction modification system, a gene cluster for mersacidin synthesis, and an orphan gene cluster devoted to non-ribosomal synthesis of an unidentified peptide. Like other members of the taxon, the Y2 genome contains giant gene clusters for non-ribosomal synthesis of the polyketides macrolactin, difficidin, and bacillaene, the antifungal lipopeptides bacillomycin D, and fengycin, the siderophore bacillibactin, and the dipeptide bacilysin. A gene cluster encoding enzymes for a degradative pathway with 2-keto-3-deoxygluconate and 2-keto-3-deoxy-phosphogluconate as intermediates was explored by genome mining and found as being a unique feature for representatives of the plantarum subspecies. A survey of the Y2 genome against other B. amyloliquefaciens genomes revealed 130 genes only occurring in subsp. plantarum but not in subsp. amyloliquefaciens. Notably, the surfactin gene cluster is not functional due to a large deletion removing parts of the Srf synthetases B and C. Expression of polyketides, lipopeptides, mersacidin, and of the growth hormone indole-3-acetic acid in Y2 was demonstrated by matrix-assisted laser desorption ionization-time of flight mass spectroscopy and high-performance liquid chromatography, respectively.

Comparative genomic analysis of the hexuronate metabolism genes and their regulation in gammaproteobacteria

The hexuronate metabolism in Escherichia coli is regulated by two related transcription factors from the FadR subfamily of the GntR family, UxuR and ExuR. UxuR controls the d-glucuronate metabolism, while ExuR represses genes involved in the metabolism of all hexuronates. We use a comparative genomics approach to reconstruct the hexuronate metabolic pathways and transcriptional regulons in gammaproteobacteria. We demonstrate differences in the binding motifs of UxuR and ExuR, identify new candidate members of the UxuR/ExuR regulons, and describe the links between the UxuR/ExuR regulons and the adjacent regulons UidR, KdgR, and YjjM. We provide experimental evidence that two predicted members of the UxuR regulon, yjjM and yjjN, are the subject of complex regulation by this transcription factor in E. coli.

Novel insights into the diversity of catabolic metabolism from ten haloarchaeal genomes

BACKGROUND

The extremely halophilic archaea are present worldwide in saline environments and have important biotechnological applications. Ten complete genomes of haloarchaea are now available, providing an opportunity for comparative analysis.

METHODOLOGY/PRINCIPAL FINDINGS

We report here the comparative analysis of five newly sequenced haloarchaeal genomes with five previously published ones. Whole genome trees based on protein sequences provide strong support for deep relationships between the ten organisms. Using a soft clustering approach, we identified 887 protein clusters present in all halophiles. Of these core clusters, 112 are not found in any other archaea and therefore constitute the haloarchaeal signature. Four of the halophiles were isolated from water, and four were isolated from soil or sediment. Although there are few habitat-specific clusters, the soil/sediment halophiles tend to have greater capacity for polysaccharide degradation, siderophore synthesis, and cell wall modification. Halorhabdus utahensis and Haloterrigena turkmenica encode over forty glycosyl hydrolases each, and may be capable of breaking down naturally occurring complex carbohydrates. H. utahensis is specialized for growth on carbohydrates and has few amino acid degradation pathways. It uses the non-oxidative pentose phosphate pathway instead of the oxidative pathway, giving it more flexibility in the metabolism of pentoses.

CONCLUSIONS

These new genomes expand our understanding of haloarchaeal catabolic pathways, providing a basis for further experimental analysis, especially with regard to carbohydrate metabolism. Halophilic glycosyl hydrolases for use in biofuel production are more likely to be found in halophiles isolated from soil or sediment.

Involvement of the leucine response transcription factor LeuO in regulation of the genes for sulfa drug efflux

LeuO, a LysR family transcription factor, exists in a wide variety of bacteria of the family Enterobacteriaceae and is involved in the regulation of as yet unidentified genes affecting the stress response and pathogenesis expression. Using genomic screening by systematic evolution of ligands by exponential enrichment (SELEX) in vitro, a total of 106 DNA sequences were isolated from 12 different regions of the Escherichia coli genome. All of the SELEX fragments formed complexes in vitro with purified LeuO. After Northern blot analysis of the putative target genes located downstream of the respective LeuO-binding sequence, a total of nine genes were found to be activated by LeuO, while three genes were repressed by LeuO. The LeuO target gene collection included several multidrug resistance genes. A phenotype microarray assay was conducted to identify the gene(s) responsible for drug resistance and the drug species that are under the control of the LeuO target gene(s). The results described herein indicate that the yjcRQP operon, one of the LeuO targets, is involved in sensitivity control against sulfa drugs. We propose to rename the yjcRQP genes the sdsRQP genes (sulfa drug sensitivity determinant).

Network evaluation from the consistency of the graph structure with the measured data

Background

A knowledge-based network, which is constructed by extracting as many relationships identified by experimental studies as possible and then superimposing them, is one of the promising approaches to investigate the associations between biological molecules. However, the molecular relationships change dynamically, depending on the conditions in a living cell, which suggests implicitly that all of the relationships in the knowledge-based network do not always exist. Here, we propose a novel method to estimate the consistency of a given network with the measured data: i) the network is quantified into a log-likelihood from the measured data, based on the Gaussian network, and ii) the probability of the likelihood corresponding to the measured data, named the graph consistency probability (GCP), is estimated based on the generalized extreme value distribution.

Results

The plausibility and the performance of the present procedure are illustrated by various graphs with simulated data, and with two types of actual gene regulatory networks in Escherichia coli: the SOS DNA repair system with the corresponding data measured by fluorescence, and a set of 29 networks with data measured under anaerobic conditions by microarray. In the simulation study, the procedure for estimating GCP is illustrated by a simple network, and the robustness of the method is scrutinized in terms of various aspects: dimensions of sampling data, parameters in the simulation study, magnitudes of data noise, and variations of network structures.

In the actual networks, the former example revealed that our method operates well for an actual network with a size similar to those of the simulated networks, and the latter example illustrated that our method can select the activated network candidates consistent with the actual data measured under specific conditions, among the many network candidates.

Conclusion

The present method shows the possibility of bridging between the static network from the literature and the corresponding measurements, and thus will shed light on the network structure variations in terms of the changes in molecular interaction mechanisms that occur in response to the environment in a living cell.

Microbial biochemistry, physiology, and biotechnology of hyperthermophilic Thermotoga species

High-throughput sequencing of microbial genomes has allowed the application of functional genomics methods to species lacking well-developed genetic systems. For the model hyperthermophile Thermotoga maritima, microarrays have been used in comparative genomic hybridization studies to investigate diversity among Thermotoga species. Transcriptional data have assisted in prediction of pathways for carbohydrate utilization, iron-sulfur cluster synthesis and repair, expolysaccharide formation, and quorum sensing. Structural genomics efforts aimed at the T. maritima proteome have yielded hundreds of high-resolution datasets and predicted functions for uncharacterized proteins. The information gained from genomics studies will be particularly useful for developing new biotechnology applications for T. maritima enzymes.

A selC-associated genomic island of the extraintestinal avian pathogenic Escherichia coli strain BEN2908 is involved in carbohydrate uptake and virulence

The complete nucleotide sequence and genetic organization of a new genomic island (AGI-3) isolated from the extraintestinal avian pathogenic Escherichia coli strain BEN2908 is reported. This 49,600-bp island is inserted at the selC locus and contains putative mobile genetic elements such as a phage-related integrase gene, transposase genes, and direct repeats. AGI-3 shows a mosaic structure of five modules. Some of these modules are present in other E. coli strains and in other pathogenic bacterial species. The gene cluster aec-35 to aec-37 of module 1 encodes proteins associated with carbohydrates assimilation such as a major facilitator superfamily transporter (Aec-36), a glycosidase (Aec-37), and a putative transcriptional regulator of the LacI family (Aec-35). The aec-35 to aec-37 cluster was found in 11.6% of the tested pathogenic and nonpathogenic E. coli strains. When present, the aec-35 to aec-37 cluster is strongly associated with the selC locus (97%). Deletion of the aec-35-aec-37 region affects the assimilation of seven carbohydrates, decreases the growth rate of the strain in minimal medium containing galacturonate or trehalose, and attenuates the virulence of E. coli BEN2908 for chickens.

GntP is the Escherichia coli Fructuronic acid transporter and belongs to the UxuR regulon

Escherichia coli has four gluconate transporters, GntP, GntU, GntT, and IdnT, which are members of the major facilitator superfamily. The physiological function of GntP was previously unknown and is the subject of this study. GntP is not induced by gluconate, and despite being located adjacent to genes involved in glucuronate catabolism, gntP does not encode a glucuronate transporter. Here we identify gntP as the gene which encodes the fructuronate transporter. We show that gntP is induced by fructuronate and is a new member of the UxuR regulon: gntP is derepressed in an uxuR strain, UxuR binds in vitro specifically to an operator site that overlaps the gntP promoter, and UxuR binding is eliminated by fructuronate. Transcription of gntP requires activation by cyclic AMP (cAMP)-cAMP receptor protein. A gntP mutant cannot grow on fructuronate but grows normally on glucuronate and gluconate. Thus, the UxuR regulon is a module of sugar acid catabolism whose physiological role is for growth on fructuronate. Glucuronate, because it proceeds through a fructuronate intermediate, must induce the UxuR regulon and must also induce the ExuR regulon, which encodes the glucuronate transporter, ExuT, and the first step in its catabolism, UxaC. Thus, hexuronate catabolism in E. coli requires both the ExuR and UxuR regulons, while fructuronate catabolism requires only the UxuR regulon.

In vitro identification of two adherence factors required for in vivo virulence of Pseudomonas fluorescens

By enriching a random transposon insertion bank of Pseudomonas fluorescens for mutants affected in their adherence to the human extracellular matrix protein fibronectin, we isolated 23 adherence minus mutants. Mutants showed a defect in their ability to develop a biofilm on an abiotic surface and were impaired for virulence when tested in an in vivo virulence model in the fruit fly, Drosophila melanogaster. Molecular characterisation of these mutants showed that the transposon insertions localised to two distinct chromosomal locations, which were subsequently cloned and characterised from two mutants. A search in the databanks identified two loci in the Pseudomonas aeruginosa PAO1 genome with significant homology to the genes interrupted by the transposon insertions. Mutant IVC6 shows homology to gmd, coding for the enzyme GDP-mannose dehydratase, involved in the synthesis of A-band- O-antigen-containing lipopolysaccharide (LPS). Mutant IVG7 is significantly similar to a probable outer membrane protein of strain PAO1, with no specific function attributed thus far, yet with significant homology to Escherichia coli FadL, involved in long-chain fatty acid transport. We propose that this protein, together with LPS, is involved in the first steps of P. fluorescens adherence leading to host colonisation. Results presented here also demonstrate the pathogenic potential of P. fluorescens, assessed in an in vivo Drosophila model system, correlated with its ability to adhere to the human extracellular matrix protein, fibronectin. Correlation between the mutant phenotypes with identified virulence factors and their actual role in the virulence of P. fluorescens is discussed.

Control of exuT activity for galacturonate transport by the negative regulator ExuR in Erwinia chrysanthemi EC16

The negative regulatory protein ExuR in Erwinia chrysanthemi regulates expression of the galacturonate uptake (exuT) and utilization (uxaA, uxaB, uxaC) genes. We cloned and determined the nucleotide sequence of the exuR gene from E. chrysanthemi EC16. Analysis of the deduced amino acid sequence indicates that this protein possesses a helix-turn-helix motif and belongs to the GntR family of transcriptional repressors. Northern blot analysis and studies with transcriptional fusions of exuT in wild-type and exuR mutant backgrounds indicate that exuT transcription is deregulated in the exuR strain in vivo and in planta. [14C]-galacturonic acid uptake was constitutively high under inducing and noninducing conditions in the exuR mutant. Maximal exuT transcription activity was observed within 8 h of bacterial inoculation into potato tubers, well before any visible symptoms of disease were detected. This suggests that ExuT transport activity in E. chrysanthemi is important in the early stages of disease development.

Regulation of hexuronate utilization in Bacillus subtilis

We have identified a locus essential for galacturonate utilization in Bacillus subtilis. Genes homologous to Escherichia coli and Erwinia chrysanthemi glucuronate and galacturonate metabolic genes were found in a cluster consisting of 10 open reading frames (ORFs) in the B. subtilis chromosome. A mutant of B. subtilis containing a replacement of the second and third ORFs was unable to grow with galacturonate as its primary carbon source. Galacturonate induced expression from a sigmaA-dependent promoter, exuP1, located upstream from the first ORF. The eighth ORF in this cluster (the exu locus) encodes a LacI and GalR homolog that negatively regulated expression from exuP1. A 26-bp inverted repeat sequence centered 15 bp downstream from the exuP1 start point of transcription acted in cis to negatively regulate expression from exuP1 under noninducing conditions. Expression from the exuP1 promoter was repressed by high levels of glucose, which is probably mediated by CcpA (catabolite control protein A). A sigmaE-dependent promoter, exuP2, was localized between the second and third ORFs and was active during sporulation.

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.

The exuT gene of Erwinia chrysanthemi EC16: nucleotide sequence, expression, localization, and relevance of the gene product

Galacturonic acid (GalUA) is a major component of pectin and polygalacturonic acid in the plant cell wall. In the phytopathogen Erwinia chrysanthemi, the uptake of molecules derived from degradation of these polymers is an important early step in the events preceding induction of pectinases, ultimately leading to plant tissue maceration. Uptake systems for GalUA and dimers of GalUA have been described and shown to be inducible in E. chrysanthemi. The GalUA uptake gene (exuT) was cloned and sequenced. Nucleotide sequence analysis identified an open reading frame encoding a 345-amino-acid polypeptide with a calculated mass of 37,825 Da. This polypeptide is predicted to be an integral membrane protein based on its high nonpolar amino acid content and hydropathic profile. Localization studies with the labeled polypeptide in the T7-RNA polymerase system also suggest that ExuT is a membrane protein. This evidence is further supported by the observation of hybrid ExuT-PhoA proteins in the bacterial cytoplasmic membrane following immunoblot analysis. Northern (RNA) analysis indicated that the gene is inducible in the presence of the monomer, GalUA. A targeted mutation in the exuT gene affected the utilization of GalUA as a role carbon source for growth. Maceration of potato tuber tissue by this mutant was delayed and reduced, when compared with the parental strain EC16.

Fermentation of biomass-derived glucuronic acid by pet expressing recombinants of E. coli B

The economics of large-scale production of fuel ethanol from biomass and wastes requires the efficient utilization of all the sugars derived from the hydrolysis of the heteropolymeric hemicellulose component of lignocellulosic feedstocks. Glucuronic and 4-O-methyl-glucuronic acids are major side chains in xylans of the grasses and hardwoods that have been targeted as potential feedstocks for the production of cellulosic ethanol. The amount of these acids is similar to that of arabinose, which is now being viewed as another potential substrate in the production of biomass-derived ethanol. This study compared the end-product distribution associated with the fermentation of D-glucose (Glc) and D-glucuronic acid (GlcUA) (as sole carbon and energy sources) by Escherichia coli B (ATCC 11303) and two different ethanologenic recombinants--a strain in which pet expression was via a multicopy plasmid (pLOI297) and a chromosomally integrated construct, strain KO11. pH-stat batch fermentations were conducted using a modified LB medium with 2% (w/v) Glc or GlcUA with the set-point for pH control at either 6.3 or 7.0. The nontransformed host culture produced only lactic acid from glucose, but fermentation of GlcUA yielded a mixture of ethanol, acetic, and lactic acids, with acetic acid being the predominant end-product. The ethanol yield associated with GlcUA fermentation by both recombinants was similar, but acetic acid was a significant by-product. Increasing the pH from 6.3 to 7.0 increased the rate of glucuronate fermentation, but it also decreased the ethanol mass yield from 0.22 to 0.19 g/g primarily because of an increase in acetic acid production. In all fermentations there was good closure of the carbon mass balance, the exception being the recombinant bearing plasmid pLOI297 that produced an unidentified product from GlcUA. The metabolism of GlcUA by this metabolically engineered construct remains unresolved. The results offered insights into metabolic fluxes and the regulation of pyruvate catabolism in the wild-type and engineered strains. End-product distribution for metabolism of glucuronic acid by the nontransformed, wild-type E. coli B and recombinant strain KO11 suggests that the enzyme pyruvate-formate lyase is not solely responsible for the production of acetylCoA from pyruvate and that derepressed pyruvate dehydrogenase may play a significant role in the metabolism of GlcUA.

Regulation of pectinolysis in Erwinia chrysanthemi

Erwinia chrysanthemi is an enterobacterium that causes various plant diseases. Its pathogenicity results from the secretion of pectinolytic enzymes responsible for the disorganization of the plant cell wall. The E. chrysanthemi strain 3937 produces two pectin methylesterases, at least seven pectate lyases, a polygalacturonase, and a pectin lyase. The extracellular degradation of the pectin leads to the formation of oligogalacturonides that are catabolized through an intracellular pathway. The pectinase genes are expressed from independent cistrons, and their transcription is favored by environmental conditions such as presence of pectin and plant extracts, stationary growth phase, low temperature, oxygen or iron limitation, and so on. Moreover, transcription of the pectin lyase gene responds to DNA-damaging agents. The differential expressions of individual pectinase genes presumably reflect their role during plant infection. The regulation of pel genes requires several regulatory systems, including the KdgR repressor, which mediates the induction of all the pectinolysis genes in the presence of pectin catabolites. KdgR also controls the genes necessary for pectinase secretion and other pectin-inducible genes not yet characterized. PecS, a cytoplasmic protein homologous to other transcriptional regulators, can bind in vitro to the regulatory regions of pectinase and cellulase genes. The PecT protein, a member of the LysR family of transcriptional regulators, represses the expression of some pectinase genes and also affects other metabolic pathways of the bacteria. Other proteins involved in global regulations, such as CRP or HNS, can bind to the regulatory regions of the pectinase genes and affect their transcription.

Molecular characterization of the Erwinia chrysanthemi kdgK gene involved in pectin degradation

The pathways of pectin and galacturonate catabolism in Erwinia chrysanthemi converge to form a common intermediate, 2-keto-3-deoxygluconate (KDG), which is phosphorylated by KDG kinase encoded by the kdgK gene. We cloned the kdgK gene of E. chrysanthemi 3937 by complementing an Escherichia coli kdgK mutation, using an RP4-derivative plasmid. One of the kdgK R-prime plasmids harbored a DNA insert of about 80 kb and carried the uxuA and uxuB genes involved in glucuronate catabolism and the celY gene coding for an E. chrysanthemi cellulase. The kdgK and celY genes were precisely located on this plasmid, and their respective transcriptional directions were determined. The nucleotide sequence of the kdgK region indicated that the kdgK reading frame is 981 bases long, corresponding to a protein of 329 amino acids with a molecular mass of 36,377 Da. Analysis of the deduced primary amino acid sequence showed that this enzyme is a new member of the PfkB family of carbohydrate kinases. Expression of kdgK is controlled by a negative regulatory gene, kdgR, which represses all the steps of pectin degradation. Near the putative promoter of the kdgK gene, we identified a putative KdgR-binding site and demonstrated that the KdgR protein specifically binds in vitro to this DNA region. The KdgR-KDG couple directly mediates the phenomenon of repression or induction. The KDG kinase, by limiting the intracellular inducer concentration, appears to be a key enzyme in induction of the whole catabolic pathway.

Molecular analysis of the Erwinia chrysanthemi region containing the kdgA and zwf genes

The pathways of pectin and galacturonate catabolism in Erwinia chrysanthemi converge to form a common intermediate, 2-keto-3-deoxygluconate, which is phosphorylated to form 2-keto-3-deoxy-6-phosphogluconate (KDGP) and then cleaved by the aldolase encoded by the kdgA gene. We cloned the kdgA gene of the E. chrysanthemi strain 3937 by complementing an Escherichia coli kdgA mutation, using an RP4-derivative plasmid. Restriction mapping of the kdgA region and isolation of kdgA-lac fusions allowed the more precise localization of the kdgA gene and determination of its transcriptional direction. The nucleotide sequence of the kdgA region indicated that the kdgA reading frame is 639 bases long, corresponding to a protein of 213 amino acids with a molecular mass of 22,187 Da. Comparison of the deduced primary amino acid sequences of the E. chrysanthemi KDGP-aldolase to the E. coli, Zymomonas mobilis and Pseudomonas putida enzymes showed that they are highly conserved. The E. chrysanthemi kdgA structural gene begins 153 bases downstream of an open reading frame that has a high homology with the zwf E. coli gene encoding glucose-6-phosphate dehydrogenase. The zwf gene is also linked to eda (kdgA) in E. coli and P. putida but genetic organization is different. Regulation of zwf and kdgA expression in E. chrysanthemi was analysed using lacZ fusions. The expression of zwf is independent of the growth rate, but is repressed in the presence of glucose. Induction of kdgA by pectin-degradation products is mediated in vivo by the negative regulatory gene kdgR, which also controls all the steps of pectin degradation.(ABSTRACT TRUNCATED AT 250 WORDS)

Plasmids with the uidA reporter gene for the detection of promoters and transcription signals

We have constructed promoter-probe plasmids, pNB4 and pNB5, based on the promoterless gene for beta-glucuronidase (uidA) of Escherichia coli. Unique restriction sites for EcoRI, SacI, KpnI, SmaI, XmaI, XbaI, SalI, SphI and HindIII in pNB4 and for HindIII, PstI and BglII in pNB5 were included upstream of the uidA structural gene. The usefulness of these plasmids was demonstrated by cloning the promoter-operator region of the E. coli uxaB gene. We observed that expression of the uxaB-uidA operon fusion followed the transcription-regulating properties of the uxaB promoter. Another construct, pNB2, can be used to detect operator and terminator signals. Recipient cells transformed with such recombinant plasmids can be revealed by growth on medium containing a chromogenic beta-glucuronidase substrate.

Hexuronate catabolism in Erwinia chrysanthemi

In the phytopathogenic enterobacterium Erwinia chrysanthemi, the catabolism of hexuronates is linked to the degradation of pectic polymers. We isolated Mu lac insertions in each gene of the hexuronate pathway and used genetic fusions with lacZ (the beta-galactosidase gene of Escherichia coli) to study the regulation of this pathway. Three independent regulatory genes (exuR, uxuR, and kdgR) were found. Galacturonate and glucuronate were converted into 2-keto-3-deoxygluconate (KDG) by separate three-step pathways encoded by the uxaC, uxaB, and uxaA genes and the uxaC, uxuB, and uxuA genes, respectively. The two aldohexuronates entered the cell by a specific transport system, encoded by exuT. Wild-type strain 3937 was unable to use glucuronate as a carbon source since glucuronate was unable to induce the exuT expression. Mutants able to use glucuronate possessed an inactivated exuR gene. The product of the regulatory gene exuR negatively controlled the expression of exuT, uxaC, uxaB, and uxaA, which was inducible in the presence of galacturonate. The two genes specifically involved in glucuronate catabolism, uxuA and uxuB, formed two independent transcriptional units regulated separately, uxuB expression was not inducible, whereas uxuA expression was induced in the presence of glucuronate and controlled by the uxuR product. KDG, the common end product of both pathways, is cleaved by the kdgK and kdgA gene products. KDG enters the cell by a specific transport system, encoded by kdgT. The regulatory gene kdgR controlled the expression of kdgT, kdgK, and kdgA and partially that of the pel genes encoding pectate-lyases. The real inducer of pectate-lyase synthesis, originating from catabolism of galacturonate or glucuronate, appeared to be KDG. The genes of E. chrysanthemi affecting hexuronate catabolism are separated into six independent transcriptional units exuT, uxaCBA, uxuA, uxuB, kdgK, and kdgA, but only three gene clusters were localized on the genetic map: exuT-uxaCBA, uxuA-uxuB-kdgK, and kdgA-exuR.

Isolation and characterization of Tn5 insertion mutants of Erwinia chrysanthemi that are deficient in polygalacturonate catabolic enzymes oligogalacturonate lyase and 3-deoxy-D-glycero-2,5-hexodiulosonate dehydrogenase

Mutants of Erwinia chrysanthemi EC16 deficient in the polygalacturonate catabolic enzymes oligogalacturonate lyase (Ogl-) and 3-deoxy-D-glycero-2,5-hexodiulosonate (ketodeoxyuronate) dehydrogenase (KduD-) were obtained by Tn5 mutagenesis using the R plasmid pJB4JI. Ogl- Exu+ (Exu+, D-galacturonate utilization) and KduD- Exu- strains macerated potato tuber tissue and utilized glucose, glycerol, and gluconate, but they did not utilize polygalacturonate, unsaturated digalacturonate, or saturated digalacturonate. Genetic and physical evidence indicated that the Ogl- mutants and a KduD- recombinant contained a single copy of Tn5 and that Tn5 (Kmr) was linked to the mutant phenotypes. In the Ogl+ parents, basal levels of oligogalacturonate lyase were present in glycerol-grown cells and induced levels were present with saturated or unsaturated digalacturonate, while oligogalacturonate lyase was undetectable under similar conditions in Ogl- strains. Pectate lyase, polygalacturonase, and ketodeoxyuronate dehydrogenase were induced in an Ogl- strain by 3-deoxy-D-glycero-2,5-hexodiulosonate and by the enzymatic products of unsaturated digalacturonate but not by the digalacturonates. The KduD- strains lacked the dehydrogenase activity but in the presence of the digalacturonates produced higher levels of pectate lyase, polygalacturonase, and oligogalacturonate lyase than the KduD+ parents did. In the KduD- strains, pectate lyase and oligogalacturonate lyase were induced by unsaturated digalacturonate in a "gratuitous" manner, suggesting an intracellular accumulation of the inducer(s). We conclude that an intermediate(s) of the ketodeoxyuronate pathway induces pectate lyase, polygalacturonase, oligogalacturonate lyase, and ketodeoxyuronate dehydrogenase in E. chrysanthemi.

Isolation and characterization of Erwinia chrysanthemi mutants defective in degradation of hexuronates

Spontaneous and Tn9-induced mutants of Erwinia chrysanthemi were isolated which affect the degradative pathway of galacturonate and ketodeoxygluconate. The mutations were characterized both biochemically and functionally by complementation analysis and localized in the E. chrysanthemi chromosome. The kdgK gene mapped very close to ile, the kdgA gene was between trp and his, and the exuT-uxaC-uxaB-uxaA cluster was linked to thy. The different types of mutants obtained were consistent with an organization of the exu-uxa cluster into two transcription units, one containing the exuT gene, and the other containing the three uxa genes, with the transcription going from uxaC to uxaA.

Characterization of the operator sites of the exu regulon in Escherichia coli K-12 by operator-constitutive mutations and repressor titration

In Escherichia coli, the exu regulon of the hexuronate system involves the three exuT, uxaCA and uxaB operons and is under the negative control of the exuR regulatory gene product. The technique developed by Casadaban, Chou and Cohen was employed to construct two plasmids containing operon fusions in which the lactose genes were fused to the uxaCA and exuT operons. These fusions were transferred into the chromosome by a reciprocal recombination event, and the resulting strains were used for isolation of mutants defective in repression. Two types of operator-constitutive mutants were obtained: one specific for the uxaCA operon expression and the other affecting the exuT gene expression. This genetic evidence confirms that these two operons which are divergently transcribed each possess their own operator site.--The derepressed expression of the two exuT-lac and uxaCA-lac operons and the uxaB gene was also examined upon introduction of plasmids bearing various operators of the exu regulon. The results of testing exuR repressor titration by multiple copies of the exu operators allowed us to show a gradation in the affinity degrees for the three exu operators: uxaBo has the strongest affinity for the exuR repressor and uxaCo the weakest, although that of exuTo seems to be just slightly greater. This gradation may play a role in the control of the exu regulon expression.

Isolation of a functional exuR-repressor-beta-galactosidase hybrid protein by use of in vitro gene fusions

The exuR regulatory gene of Escherichia coli codes for a repressor molecule that controls negatively the expression of the exu regulon genes involved in the hexuronate degradation. The exuR gene was fused to the lacZ gene in vitro on plasmid cloning vectors developed by Casadaban et al. [J. Bacteriol. 143 (1980) 971-980]. The exuR-lacZ fusion gene allows the production of hybrid molecules possessing in a single polypeptide beta-galactosidase activity as well as the capacity to bind in vivo specifically to the operators of the exu operons. However, the affinity of ExuR hybrid protein for the exu operators seems to be reduced in comparison with the native repressor since, even overproduced in the cell, the chimeric polypeptide was not able to completely repress the expression of the exu operons. The other functions of the ExuR repressor, i.e., repression of the uxuAB operon and inactivation by the inducers, were not retained in the chimeric protein. This particular chimaera of Mr about 120 000 was purified by chromatography on phosphocellulose from strains carrying the fusion plasmids. The purified polypeptide was able to repress in vitro the synthesis of an exu gene product in a cell-free transcription and translation system. The implications of the repressor activity in the chimeric protein are discussed. The NH2-terminus of ExuR repressor probably recognizes the exu operators specifically, and this region represents less than 20% of the entire ExuR molecule.

Physical mapping of the exuT and uxaC operators by use of exu plasmids and generation of deletion mutants in vitro

Operons uxaCA and exuT of the hexuronate system are very closely linked on the Escherichia coli genetic map. Using plasmid vectors constructed by Casadaban et al. (J. Bacteriol. 143:971-980, 1980), we formed exuT-lacZ and uxaA-lacZ fusions in vitro. The phenotypic properties of the new plasmids allowed us to confirm that the exuT and uxaCA operons are divergently transcribed. An analysis of these fusion plasmids and derivatives in the presence of multiple copies of the exuR regulatory gene demonstrated that the two operons possess separate control regions. The precise location of the operator site relative to endonuclease restriction sites was determined. In addition, deletions of different lengths were generated on exu plasmids by restriction enzymes and were recombined into the chromosome. The expression of the exu regulon genes in the resulting deletion mutants is in agreement with the postulated location of the exuT and uxaCA operators in the fusion plasmids.

Interchangeability of repressors for the control of the uxu and uid operons in E. coli K12

The uidA and uxuAB operons are each under the dual control of two repressor molecules: the uidR and uxuR encoded repressors negatively control the uidA operon whereas the uxuAB operon is regulated by the uxuR and exuR gene products. Plasmids overproducing the regulatory molecules encoded by exuR, uxuR, or uidR were used to investigate the regulation of these two operons. Large amounts of either exuR or uxuR repressor caused a complete repression of the uxuAB operon in exuR and uxuR double-deleted mutants, suggesting that the two repressors, when they are overproduced, are totally interchangeable for the control of the uxuAB operon. In contrast, the UxuR molecule has no effect on the other exu regulon operons controlled by the exuR gene product. The uidR and uxuR gene products appear to be partially interchangeable for the regulation of the uidA gene since addition of multicopy plasmids bearing uidR+, in uxuR deleted mutant strains, only partially suppresses the derepression of the uidA gene. Inversely, multicopies of uidR weakly reduced the synthesis of the uxuB gene product in uxuR derepressed mutants. The restrictions placed by these phenomena on the formulation of the mechanism of cooperation between the two repressor molecules for repressing the uxuAB and uidA operons are discussed.

In vivo cloning of Erwinia carotovora genes involved in the catabolism of hexuronates

Using the RP4::mini-Mu pULB113 plasmid, an RP4 derivative carrying a deleted Mu prophage which allows the plasmid to pick up any chromosomal DNA segment to form R' plasmids, we cloned all of the genes of Erwinia carotovora involved in the catabolism of the hexuronates and in the transport of these substrates. With the R' plasmids we isolated, we performed complementation analysis and found that, in the Erwinia carotovora strain we used, the genes involved in the catabolism of the hexuronates are clustered in four regions of the chromosome. This genetic organization is compared with that of Escherichia coli K-12.

Aldohexuronate transport system in Erwinia carotovora

The biochemical and physiological aspects of hexuronate transport in Erwinia carotovora were studied to approach the genetic regulation of the hexuronate degradative pathway in this bacterial species. An active transport system for glucuronate and galacturonate uptake exists in E. carotovora. The glucuronate entry reaction displayed saturation kinetics with an apparent Km of 0.05 mM (at 25 degrees C; pH 7). Galacturonate appeared to be a competitive inhibitor of glucuronate uptake with a Ki of 0.1 mM. Glucuronate permeation was not induced by glucuronate itself in wild-type strains. Galacturonate induced the uptake of glucuronate (about fivefold). The induced synthesis of the transport system was sensitive to catabolite repression by glucose. Mutants able to grow on glucuronate as the sole carbon source showed constitutive synthesis of the hexuronate transport system.

Construction of hybrid plasmids containing the Escherichia coli uxaB gene: analysis of its regulation and direction of transcription

The uxaB gene of Escherichia coli, encoding for altronate oxidoreductase involved in the hexuronate degradative pathway, was isolated on a ColE1-uxaB hybrid plasmid from the Clarke and Carbon bank. The restriction map of this plasmid was established. The uxaB gene was mapped on a 1.5-megadalton HindIII-KpnI DNA fragment. Use of an in vitro gene fusion between uxaB and lacZ genes led to the determination that uxaB is transcribed from the KpnI towards the HindIII restriction sites. Gene amplification in cells containing various uxaB hybrid plasmids allowed us to show a gradation in the level of repression of exu operator sites by the exuR regulatory gene product.

Determination of the transcription direction of the exuT gene in Escherichia coli K-12: divergent transcription of the exuT-uxaCA operons

The exuT gene of Escherichia coli, coding for the hexuronate transport system, was fused to lac genes by the use of Mu d(Apr lac) insertions (M. J. Casadaban and S. Cohen, Proc. Natl. Acad. Sci. U.S.A. 76:4530-4533, 1979). The method of chromosome mobilization with F' lac::Mu episomes (J. B. Zeldis, A. I. Bukhari, and D. Zipser, Virology 55:289-294, 1974) made it possible to determine the transcription direction of the exuT gene from the orientation of the Mu d(Apr lac) insertion in the fusion strains. Our results for a exuT-lac fusion strain suggest that the direction of transcription of other single gene operon exuT is clockwise on the standard E. coli map and confirm that the direction of transcription of uxaC is counterclockwise. The two close operons exuT and uxaCA are thus transcribed in opposite directions.

Use of in vitro gene fusions to study the uxuR regulatory gene in Escherichia coli K-12: direction of transcription and regulation of its expression

The uxuAB operon is composed of two genes coding for enzymes involved in hexuronate degradation. This operon is negatively controlled by the uxuR and exuR regulatory gene products. Fusions that brought lac gene expression under the control of transcriptional and translational signals within the uxuR gene were used to study uxuR regulation. These fusions were formed on plasmid cloning vectors constructed by Casadaban et al. (J. Bacteriol. 143:971-980, 1980). The transcriptional direction of the uxuR gene was deduced from the restriction pattern and the phenotypic properties of the new plasmids. The gene is transcribed counterclockwise on the standard Escherichia coli map, as is the uxuAB operon. Introduction in trans of a compatible plasmid carrying a wild-type uxuR gene in the lac fusion plasmid containing strain resulted in a decrease of beta-galactosidase synthesis. It was concluded that expression of the uxuR gene itself is repressed by its own product. The two other types of regulation found in the uxuAB operon, i.e., induction by fructuronate and catabolite control, also apply to the uxuR gene, whereas repression by the exuR repressor does not seem to occur for the uxuR gene.

Isolation of fusions between the lac genes and several genes of the exu regulon: analysis of their regulation, determination of the transcription direction of the uxaC-uxaA operon, in Escherichia coli K-12

Gene fusions between the lac structural genes and different genes of the hexuronate system were isolated by the two methods described by Casadaban (1976, 1979). Mud (Apr lac) mutants which have the lac genes fused to the regulatory region of exuT, uxaC, uxaA and uxaB genes were constructed. Separately, the lac genes carried by a lambda plac-Mu hybrid phage were placed into a Mucts prophage inserted into uxaC gene and fusions were obtained, by selection of deletions putting the lac genes under the control of the uxaC regulatory elements. Induction of the lysogen led to the isolation of a lambda transducing phage bearing this uxaC-lac fusion. In all the fusion strains, beta-galactosidase expression was shown to be inducible by the natural inducers of hexuronate system enzymes, sensitive to catabolite repression and under the negative control of the exuR regulatory gene. The mutants with Mu insertion were used to establish the direction of transcription of the uxaC-uxaA operon, which is counter-clockwise on the circular genetic map of Escherichia coli (from uxaC to uxaA).

Regulation of hexuronate system genes in Escherichia coli K-12: multiple regulation of the uxu operon by exuR and uxuR gene products

New regulatory mutants of Escherichia coli K-1 carrying alterations of the uxuR gene were isolated and characterized. In the presence of superrepressed or derepressed uxuR mutations, mannonic hydrolyase (uxuA) and oxidoreductase relationship analyses suggested that the uxuR gene product acted as a repressor in the control of uxuA-uxuB operon expression. uxuR mutations were localized near min 97, and the following gene order was established: (argH)-uxuR-uxuB-uxuA-(thr). Properties of exuR (point and deletion) mutants showed that both exuR and uxuR regulatory gene products were involved in the control of the uxuA uxuB operon. Analysis of exuR uxuR double-derepressed mutants suggested that exuR and uxuR repressors act cooperatively to repress the uxu operon.