[Metabolism of hexuronides and hexuronates in Escherichia coli K12: physiologic and genetic aspects of its regulation]

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.

A 35.7 kb DNA fragment from the Bacillus subtilis chromosome containing a putative 12.3 kb operon involved in hexuronate catabolism and a perfectly symmetrical hypothetical catabolite-responsive element

The Bacillus subtilis strain 168 chromosomal region extending from 109 degrees to 112 degrees has been sequenced. Among the 35 ORFs identified, cotT and rapA were the only genes that had been previously mapped and sequenced. Out of ten ORFs belonging to a single putative transcription unit, seven are probably involved in hexuronate catabolism. Their sequences are homologous to Escherichia coli genes exuT, uidB, uxaA, uxaB, uxaC, uxuA and uxuB, which are all required for the uptake of free D-glucuronate, D-galacturonate and beta-glucuronide, and their transformation into glyceraldehyde 3-phosphate and pyruvate via 2-keto-3-deoxygluconate. The remaining three ORFs encode two dehydrogenases and a transcriptional regulator. The operon is preceded by a putative catabolite-responsive element (CRE), located between a hypothetical promoter and the RBS of the first gene. This element, the longest and the only so far described that is fully symmetrical, consists of a 26 bp palindrome matching the theoretical B. subtilis CRE sequence. The remaining predicted amino acid sequences that share homologies with other proteins comprise: a cytochrome P-450, a glycosyltransferase, an ATP-binding cassette transporter, a protein similar to the formate dehydrogenase alpha-subunit (FdhA), protein similar to NADH dehydrogenases, and three homologues of polypeptides that have undefined functions.

A mutant crp allele that differentially activates the operons of the fuc regulon in Escherichia coli

L-Fucose is used by Escherichia coli through an inducible pathway mediated by a fucP-encoded permease, a fucI-encoded isomerase, a fucK-encoded kinase, and a fucA-encoded aldolase. The adolase catalyzes the formation of dihydroxyacetone phosphate and L-lactaldehyde. Anaerobically, lactaldehyde is converted by a fucO-encoded oxidoreductase to L-1,2-propanediol, which is excreted. The fuc genes belong to a regulon comprising four linked operons: fucO, fucA, fucPIK, and fucR. The positive regulator encoded by fucR responds to fuculose 1-phosphate as the effector. Mutants serially selected for aerobic growth on propanediol became constitutive in fucO and fucA [fucO(Con) fucA(Con)], but noninducible in fucPIK [fucPIK(Non)]. An external suppressor mutation that restored growth on fucose caused constitutive expression of fucPIK. Results from this study indicate that this suppressor mutation occurred in crp, which encodes the cyclic AMP-binding (or receptor) protein. When the suppressor allele (crp-201) was transduced into wild-type strains, the recipient became fucose negative and fucose sensitive (with glycerol as the carbon and energy source) because of impaired expression of fucA. The fucPIK operon became hyperinducible. The growth rate on maltose was significantly reduced, but growth on L-rhamnose, D-galactose, L-arabinose, glycerol, or glycerol 3-phosphate was close to normal. Lysogenization of fuc+ crp-201 cells by a lambda bacteriophage bearing crp+ restored normal growth ability on fucose. In contrast, lysogenization of [fucO(Con)fucA(Con)fucPIK(Non)crp-201] cells by the same phage retarded their growth on fucose.

The role of iron in the activation of mannonic and altronic acid hydratases, two Fe-requiring hydro-lyases

D-Altronate hydratase and D-mannonate hydratase belong to a class of Fe2+-requiring enzymes, but the function of iron in these enzymes is largely unknown. Methods are described for the convenient preparation of both these hydratases from Escherichia coli and studies related to metal activation are presented. The enzymes are inactive in the absence of a bivalent metal and a reducing agent such as dithiothreitol. Fe2+ at low concentrations activates the enzymes efficiently, but inhibits them over 2 mM. Furthermore Mn2+ is also capable of activating aldonic acid hydratases and appears to be a constituent of the enzyme active center. A marked synergistic activation is observed in the presence of both ions, raising the possibility that the enzyme has two binding sites for ions. Upon activation, the two aldonic acid hydratases incorporate a single Fe atom and contain no Fe-S core, in contrast to other characterized Fe-hydratases, such as aconitase or maleic acid hydratase. The incorporated iron is losely bound (with Kd about 4.5 mM and 20 mM for mannonate and altronate hydratase, respectively) and can be readily removed with EDTA. The enzymes exhibit no requirement for sulphide ions and are insensitive to thiol reagents. A first-order inhibition is observed with iron chelators and can be removed by competition with excess metal ions. No change in the absorption spectra is observed upon oxidation-reduction or activation with metals. The activated enzymes exhibit no electron paramagnetic (EPR) spectrum under anaerobic conditions; in the presence of oxygen, an intense EPR spectrum develops in Fe2+-activated samples with signal at g = 1.98, which upon reaction of the enzyme with the substrate moves into a species with signals at g = 4.15 and g = 9.07, with EPR parameters very similar to those of oxidized rubredoxins.

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.

Escherichia coli K-12 structural kdgT mutants exhibiting thermosensitive 2-keto-3-deoxy-D-gluconate uptake

A specific method is described for selecting thermosensitive mutants of Escherichia coli K-12 able to grow on 2-keto-3-deoxy-D-gluconate (KDG) and D-glucuronate at 2, but not at 42 degrees C. The extensive analysis of one such mutant is consistent with the conclusion that the carrier molecule responsible for KDG and glucuronate uptake becomes thermolabile. (i) Growth on a variety of carbon sources is perfectly normal at 28 and 42 degrees C, whereas in the same temperature range it gradually diminishes on KDG and glucuronate. (ii) The apparent Km value for KDG is about twofold in the range 25 to 40 degrees C. In the same temperature range, the Vmax values for KDG influx are higher for the mutant compared with those of the wild-type strain, but the optimum temperature is 34 degrees C instead of 38 degrees C. On the contrary, the Vmax values for glucuronate influx are lower for the mutant than for the parental strain, and the optimum temperature for both strains is shifted beyond 40 degrees C. (iii) The activation energies for KDG and glucuronate uptake are about twofold higher in the mutant than in the wild-type strain. (iv) Kinetics of counterflow under deenergized conditions (overshoot) at different temperatures indicate that the defect is located in the translocation step rather than in the processes involved in energy coupling. (v) The first-order rate constants for thermal denaturation are, respectively, 2.5- and 5-fold higher at 40 and 30 degrees C in the mutant than in the wild-type strain, and the activation energy for thermal denaturation is lower. (vi) The carrier molecule in the mutant is also much more sensitive to denaturation by N-ethylmaleimide. (vii) Four independent thermosensitive mutations and one revertatn were located by transduction in or near the kdgT locus, defined previously as the site of nonconditional KDG transport-negative mutations. These results support the conclusion that kdgT represents the structural gene coding for the KDG transport system.

Physiological and genetic regulation of the aldohexuronate transport system in Escherichia coli

In Escherichia coli K-12, the specificity of the aldohexuronate transport system (THU) is restricted to glucuronate and galacturonate. There is a relatively high basal-level activity in uninduced wild-type or isomeraseless strains. Supplementary activity is obtained with the inducers mannonic amide (five-fold), galacturonate (fourfold), fructuronate (fivefold), and tagaturonate (sevenfold). Specific THU- mutants were selected as strains unable to grow on either aldohexuronate but able to grow on fructuronate or tagaturonate. The remaining transport activity in uninduced and induced THU- starins represents less than 20% of that found in the wild type. Conjugation and transduction experiments indicate that all of the THU- mutations are located in a unique locus, exuT, half-way between the tolC (59 min) and argG (61 min) markers. exuT is closely linked to the uxaC-uxaA operon (60 min) and to the regulatory gene exuR (60 min), which controls the above-mentioned operon and the uxaB operon (45 min). Growth on either aldohexuronate and transport activity are fully recovered when exuT mutants are allowed to revert to exuT+ on galacturonate or glucuronate. Reversion on glucuronate alone may lead to the mutational derepression of the 2-keto-3-deoxygluconate transport system, which is uninducible in the wild type, which also takes up glucuronate, and whose structural gene belongs to the kdg regulon. Such strains, which remain unable to grow on galacturonate, are exuT and kdgR (constitutive allele of the regulatory gene kdgR of the kdg regulon). THU activity is superrepressed in an exuR mutant in which the uxaC-uxaA operon and the uxaB operon are superrepressed; exuR+/exuR merodiploids are also superrepressed. In a thermosensitive exuR mutant in which the above-mentioned operons are constitutive at 42 degrees C, the THU activity is fully derepressed at this temperature. On the basis of these and other results, it is concluded that THU is coded for by the structural gene exuT, which is negatively controlled by the exuR gene product and which probably belongs to an operon distinct from the uxaA-uxaC operon.

Regulation of beta-glucuronidase synthesis in Escherichia coli K-12: constitutive mutants specifically derepressed for uidA expression

All methyl-beta-D-galacturonide-positive mutants isolated from Escherichia coli K-12 carry constitutive mutations for beta-glucuronidase (UID) synthesis. Most of these mutants are specific for UID synthesis and are distributed in three classes according to the derepression level of UID. Each specific mutant carries a mutation(s) near uidA, the structural gene for UID, at min 30.5 of the E. coli K-12 linkage map. The expression of UID synthesis in F-merodiploid strains carrying these mutations permits discrimination between dominant and recessive constitutivity over the wild-type allele. The first kind of mutation (dominant) should affect the operator site uidO of the structural gene uidA; the second type of mutation (recessive) should affect a regulatory gene, uidR, operating through a negative control. The isolation of mutants bearing at this locus superrepressed mutations, which can revert to produce a constitutive phenotype, confirms the occurrence of such a regulatory gene. The partially derepressed uidR mutants of the first class are normally inducible and remain constitutive at low temperature; their UID has the same thermal sensitivity as in the wild-type strains. The occurrence of similar regulatory gene mutants has been recently described in the lactose system (Shineberg, 1974).

Regulation of beta-glucuronidase synthesis in Escherichia coli K-12: pleiotropic constitutive mutations affecting uxu and uidA expression

Among the beta-glucuronidase (UID)-constitutive mutants obtained by growth on methyl-beta-D-galacturonide, some strains are also derepressed for the two enzymes of the uxu operon: mannonate oxidoreductase (MOR) and mannonate hydrolyase (HLM). By conjugation and transduction experiments, two distinct constitutive mutations were separated in each pleiotropic mutant strain. One of them was specific for uidA gene expression and was characterized as affecting either uidO or uidR sites. The second type of mutation was mapped close to the uxu operon and was found to be responsible for the pleiotropic effect revealed in the primary mutants: after separation such a mutation still fully derepresses MOR and HLM synthesis but weakly derepresses UID synthesis. The pleiotropic effect of this mutation was maintained even though the activity of the structural genes was altered. This rules out the occurrence of an internal derepressing interaction between these enzymes. In merodiploid strains, uxu-linked constitutive mutations were recessive to the wild-type allele, suggesting that these mutations could affect a regulatory gene. The uxuR gene is probably a specific regulatory gene for a very close operon, uxu. Moreover, it has a weak effect on uidA expression. Thus, UID synthesis would be negatively controlled through the activity of two repressor molecules that are synthesized by two distinct regulatory genes, uidR and uxuR. These two repressing factors are antagonized, respectively, by phenyl-thio-beta-D-glucuronide and mannonic amide and could cooperate in a unique repression/induction control over uidA expression. Constitutive mutations affecting the control sites of uidA gene probably characterize two distinct attachment sites in the operator locus for each of the repressor molecules.

The energy-coupling controlled efflux of 2-keto-3-deoxy-D-gluconate in Escherichia coli K 12

Experiments were devised to test the plausibility and the predictions of a efflux rate equation which was previously derived [10]9 1. 2-Keto-3-deoxy-D-gluconate transport system conforms with universal laws relating zero-trans influx, influx at steady-state, steady-state levels of accumulation to external and internal substrate concentrations. 2. Full-time-course uptake kinetics fit the linearized graphical representation that can be inferred from the integrated rate equation. 3. Influx does not depend upon internal substrate concentration nor upon energy-coupling. 4. Zero-trans outflux (leak inot empty medium) is a first-order process (rate constant: 0.02 min-1) and not mediated by the carrier. Absence of cis-competition with D-glucuronate is in agreement with a simple diffusion mechanism. 5. Outflux increases when external substrate concentration is raised (counterflow). Outflux at steady-state equilibrates influx, and is a first-order process (rate constant: 0.15 min-1). 6. Uncoupling with azide leads to accelerate zero-trans outflux by a factor of 2-3. No further acceleration is obtained when other classical uncouplers are used. The process remains first-order, independent of the amount of carrier, and is accelerated by the presence of internal D-glucuronate as a result from trans-inhibition of the recapture. 7. Exchange outflux is all the more accelerated by azide as the carrier is less saturated. The process is clearly carrier-mediated and the outflux rate obeys a Michaelis law with respect to internal concentration. V is equal to V for influx. 8. Homo and hetero-overshoot experiments are in agreement with the participation of the carrier for mediating influx as well as outflux. 9. The kinetics of D-glucuronate outflux in a strain lacking the specific hexuronate permease but carrying the 2-keto-3-deoxy-D-glucuronate permease are similar to those obtained with 2-keto-3-deoxy-D-gluconate. We draw the conclusion that energy-coupling promotes the adjustment of outflux without interfering with influx rate. It apparently acts by reducing, in a continuous range, the affinity of the carrier facing inwards. The discussion is focused on the comparison with previously published models and on possible molecular mechanisms.

Inducibility of beta-glucuronidase in wild-type and hexuronate-negative mutants of Escherichia coli K-12

In strain K-12 of Escherichia coli, beta-glucuronidase synthesis was induced only by beta-glucuronides: all intermediates of the hexuronate pathway able to enter the cells failed to induce the enzyme significantly. The induction pattern of beta-glucuronidase clearly differentiates the mode of regulation of its synthesis from those of the subsequent enzymes of the pathway, which are induced by fructuronate and/or tagaturonate. In mutant strains blocked in glucuronate metabolism after the isomerase step, beta-glucuronidase synthesis was still induced by a beta-glucuronide. Glucuronate and fructuronate, which are accumulated and mutually interconverted within the cells, become good inducers of beta-glucuronidase: they induce up to a level one-half that obtained in the wild-type strain in the presence of beta-glucuronide alone. In an isomerase-negative strain where fructuronate is not produced, beta-glucuronidase was no longer induced by beta-glucuronide unless supplemented with fructuronate. In this strain, glucuronate alone or fructuronate alone exhibited greater inducing ability than in the wild-type strain. Moreover, fructuronate could also enhance glucuronate-induced synthesis of beta-glucuronidase. Glucuronate was not able to activate beta-glucuronideinduced synthesis of beta-glucuronidase. Therefore, the induction of beta-glucuronidase synthesis depends upon two factors which, when acting separately, are both poor inducers but can act cooperatively; one factor is beta-glucuronide or glucuronate and the second is fructuronate. The specific inducing capacity of each of these three compounds as well as the hypothetical mechanism(s) of the action of fructuronate are discussed.