[Colorimetric determinations of aldonate oxidoreductases of Escherichia coli K 12: applications]

Genetic analysis of uxuR and exuR genes: evidence for ExuR and UxuR monomer repressors interactions

The uxuAB operon is under the dual control of uxuR- and exuR-encoded repressors whereas the exu regulon genes are regulated by the sole ExuR repressor. Mutations affecting the two exuR and uxuR regulatory genes were selected to investigate the relationship between the two repressors. The isolation of exuR and uxuR negative dominant mutations on a multicopy plasmid indicated that the active form of the two repressors was multimeric. The introduction of a uxuR negative dominant allele into a wild-type strain resulted in a significant increase in exu gene expression. This unexpected effect may have been the consequence of the formation of hybrid repressor molecules. This protein must be composed of native ExuR+ subunits aggregated with altered UxuR subunits. The same interference was observed for the exuR negative dominant allele on uxu gene derepression. The hypothesis given here implies that the two regions of the ExuR and UxuR repressors involved in the subunit aggregation present enough homologies to allow the formation of hybrid repressor molecules.

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.

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.

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.

Molecular cloning of Escherichia coli K-12 hexuronate system genes: exu region

Lambda transducing bacteriophages carrying the exu region (min 66) of Escherichia coli K-12 (lambda pexu) were previously isolated. A restriction map of these phages is presented. Starting from the lambda pexu phage deoxyribonucleic acid, various endonuclease-generated exu fragments were subcloned into multicopy plasmid vectors, using in vitro recombination techniques. The precise location of the exu genes, relative to the endonuclease sites, was determined. Plasmids carrying uxaC and uxaA genes overproduced the corresponding enzymes 30- to 40-fold. When these plasmids were expressed in an in vitro protein-synthesizing system, two polypeptides of 50,500 and 53,000 molecular weights appeared and were identified as the uxaC and uxaA gene products. A 2.6-kilobase-pair deoxyribonucleic acid fragment was shown to code for a functional exuR repressor which controls the expression of the exu region. Plasmids containing this fragment overproduced the regulatory protein. It was possible to localize the operator region, uxaCo, which overlapped a PstI endonuclease site, and to confirm the transcriptional direction of the uxaC-uxaA operon from uxaC to uxaA.

Construction and expression of hybrid plasmids containing Escherichia coli K-12 uxu genes

The three genes of the Escherichia coli K-12 uxu region (uxu operon and regulatory gene) were isolated on a ColE1-uxu hybrid plasmid from the bank of Clarke and Carbon, and a restriction map of this region was established. In vitro recombination techniques were used to subclone the uxu restriction fragments into the plasmid vector pBR322 or pBR325. The various chimeric plasmids obtained were analyzed by restriction mapping and characterized genetically by introducing them in uxu mutant or wild-type strains. Differential rates of synthesis of the enzymes coded for by the uxu region were measured in the plasmid-containing strains; amplification of the products of the cloned genes was up to 40-fold the level found in haploid strains. The enzymes coded for by uxuA and uxuB were synthesized in vitro in a coupled transcription-translation system, confirming the results of the cloning experiments. The restriction analysis also suggests that the transcriptional direction of the uxu operon is from uxuA to uxuB and that the order of the loci in this region is: uxuR (regulatory gene), uxuB, uxuA, uxuAp (promoter), uxuAo (operator).

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

Two types of Escherichia coli K-12 regulatory mutants, partially or totally negative for the induction of the five catabolic enzymes (uronic isomerase, uxaC; altronate oxidized nicotinamide adenine dinucleotide: uxaB; mannonate hydrolyase, uxuA) and the transport system (exuT) of the hexuronate-inducible pathway, were isolated and analyzed enzymatically. Hexuronate-catabolizing revertants of the negative mutants showed a constitutive synthesis for some or all of these enzymes. Negative and constitutive mutations were localized in the same genetic locus, called exuR, and the following order for the markers situated between the min 65 and 68 was determined: argG--exuR--exuT--uxaC--uxaA--tolC. The enzymatic characterization of the pleiotropic negative and constitutive mutants of the exuR gene suggests that the exuR regulatory gene product exerts a specific and total control on the three exuT, uszB, and uxaC-uxaA operons of the galacturonate pathway and a partial control on the uxuA-uxuB operon of the glucuronate pathway. The analysis of diploid strains conatining both the wild type and a negative or constitutive allele of the exuR gene, as well as the analysis of thermosensitive mutants of the exuR gene, was in agreement with a negative regulatory mechanism for the control of the hexuronate 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.