Dual control by regulators, GntH and GntR, of the GntII genes for gluconate metabolism in Escherichia coli

Escherichia coli possesses two systems, GntI and GntII, for gluconate uptake and catabolism, whose genes are regulated by GntR as a repressor and GntH as an activator, respectively. Additionally, GntH exerts negative control of the GntI genes via the same binding element as that of GntR. We thus examined whether GntR involves regulation of the GntII genes or not. This regulation and the control by GntH were examined by using single-copy LACZ operon fusions and by RT-PCR, suggesting positive and negative regulation by GntR and positive regulation by GntH. Moreover, the introduction of mutations into possible GntR-binding elements revealed that both regulators share at least one of the elements. The results presented allow us to speculate that GntR initiates expression of the GntII genes, followed by their large induction by GntH when cells were grown in gluconate minimum medium. As in the case of the GntI genes, such a cross-regulation between the GntI and GntII via the two regulators may be important for cells to grow with gluconate.     

Cloning and molecular genetic characterization of the Escherichia coli gntR, gntK, and gntU genes of GntI, the main system for gluconate metabolism.

Three genes involved in gluconate metabolism, gntR, gntK, and gntU, which code for a regulatory protein, a gluconate kinase, and a gluconate transporter, respectively, were cloned from Escherichia coli K-12 on the basis of their known locations on the genomic restriction map. The gene order is gntU, gntK, and gntR, which are immediately adjacent to asd at 77.0 min, and all three genes are transcribed in the counterclockwise direction. The gntR product is 331 amino acids long, with a helix-turn-helix motif typical of a regulatory protein. The gntK gene encodes a 175-amino-acid polypeptide that has an ATP-binding motif similar to those found in other sugar kinases. While GntK does not show significant sequence similarity to any known sugar kinases, it is 45% identical to a second putative gluconate kinase from E. coli,gntV. The 445-amino-acid sequence encoded by gntU has a secondary structure typical of membrane-spanning transport proteins and is 37% identical to the gntP product from Bacillus subtilis. Kinetic analysis of GntU indicates an apparent Km for gluconate of 212 microM, indicating that this is a low-affinity transporter. Studies demonstrate that the gntR gene is monocistronic, while the gntU and gntK genes, which are separated by only 3 bp, form an operon. Expression of gntR is essentially constitutive, while expression of gntKU is induced by gluconate and is subject to fourfold glucose catabolite repression. These results confirm that gntK and gntU, together with another gluconate transport gene, gntT, constitute the GntI system for gluconate utilization, under control of the gntR gene product, which is also responsible for induction of the edd and eda genes of the Entner-Doudoroff pathway.     

Bacillus subtilis gnt repressor mutants that diminish gluconate-binding ability.

The Bacillus subtilis gnt operon is negatively regulated by GntR, which is antagonized by gluconate. Three GntR mutants with diminished gluconate-binding ability were obtained. Two were missense mutants (Met-209 to Ile and Ser-230 to Leu), whereas the third had a deletion of the C-terminal 23 amino acids. The mutant GntR proteins were unable to become properly detached from the gnt operator even in the presence of gluconate.     

The subsidiary GntII system for gluconate metabolism in Escherichia coli: alternative induction of the gntV gene

Two systems are involved in the transport and phosphorylation of gluconate in Escherichia coli. GntI, the main system, consists of high and low-affinity gluconate transporters and a thermoresistant gluconokinase for its phosphorylation. The corresponding genes, gntT, gntU and gntK at 76.5 min, are induced by gluconate. GntII, the subsidiary system, includes IdnT and GntV, which duplicate activities of transport and phosphorylation of gluconate, respectively. Gene gntV at 96.8 min is divergently transcribed from the idnDOTR operon involved in L-idonate metabolism. These genetic elements are induced by the substrate or 5-keto-D-gluconate. Because gntV is also induced in cells grown in gluconate, it was of interest to investigate its expression in this condition. E. coli gntK, idnOokan mutants were constructed to study this question. These idnO kan-cassete inserted mutants, unable to convert gluconate to 5-keto-D-gluconate, permitted examining gntV expression in the absence of this inducer and demonstrating that it is not required when the cells grow in gluconate. The results suggest that E. coli gntV gene is alternatively induced by 5-keto-D-gluconate or gluconate in cells cultivated either in idonate or gluconate. In this way, the control of gntV expression would seem to be involved in the efficient utilization of these substrates.     

Loss of protein kinase-catalyzed phosphorylation of HPr, a phosphocarrier protein of the phosphotransferase system, by mutation of the ptsH gene confers catabolite repression resistance to several catabolic genes of Bacillus subtilis.

In gram-positive bacteria, HPr, a phosphocarrier protein of the phosphoenolpyruvate:sugar phosphotransferase system (PTS), is phosphorylated by an ATP-dependent, metabolite-activated protein kinase on seryl residue 46. In a Bacillus subtilis mutant strain in which Ser-46 of HPr was replaced with a nonphosphorylatable alanyl residue (ptsH1 mutation), synthesis of gluconate kinase, glucitol dehydrogenase, mannitol-1-P dehydrogenase and the mannitol-specific PTS permease was completely relieved from repression by glucose, fructose, or mannitol, whereas synthesis of inositol dehydrogenase was partially relieved from catabolite repression and synthesis of alpha-glucosidase and glycerol kinase was still subject to catabolite repression. When the S46A mutation in HPr was reverted to give S46 wild-type HPr, expression of gluconate kinase and glucitol dehydrogenase regained full sensitivity to repression by PTS sugars. These results suggest that phosphorylation of HPr at Ser-46 is directly or indirectly involved in catabolite repression. A strain deleted for the ptsGHI genes was transformed with plasmids expressing either the wild-type ptsH gene or various S46 mutant ptsH genes (S46A or S46D). Expression of the gene encoding S46D HPr, having a structure similar to that of P-ser-HPr according to nuclear magnetic resonance data, caused significant reduction of gluconate kinase activity, whereas expression of the genes encoding wild-type or S46A HPr had no effect on this enzyme activity. When the promoterless lacZ gene was put under the control of the gnt promoter and was subsequently incorporated into the amyE gene on the B. subtilis chromosome, expression of beta-galactosidase was inducible by gluconate and repressed by glucose. However, we observed no repression of beta-galactosidase activity in a strain carrying the ptsH1 mutation. Additionally, we investigated a ccpA mutant strain and observed that all of the enzymes which we found to be relieved from carbon catabolite repression in the ptsH1 mutant strain were also insensitive to catabolite repression in the ccpA mutant. Enzymes that were repressed in the ptsH1 mutant were also repressed in the ccpA mutant.     

Determination of the cis sequence involved in catabolite repression of the Bacillus subtilis gnt operon; implication of a consensus sequence in catabolite repression in the genus Bacillus.

The mechanism underlying catabolite repression in Bacillus species remains unsolved. The gluconate (gnt) operon of Bacillus subtilis is one of the catabolic operons which is under catabolite repression. To identify the cis sequence involved in catabolite repression of the gnt operon, we performed deletion analysis of a DNA fragment carrying the gnt promoter and the gntR gene, which had been cloned into the promoter probe vector, pWP19. Deletion of the region upstream of the gnt promoter did not affect catabolite repression. Further deletion analysis of the gnt promoter and gntR coding region was carried out after restoration of promoter activity through the insertion of internal constitutive promoters of the gnt operon before the gntR gene (P2 and P3). These deletions revealed that the cis sequence involved in catabolite repression of the gnt operon is located between nucleotide positions +137 and +148. This DNA segment contains a sequence, ATTGAAAG, which may be implicated as a consensus sequence involved in catabolite repression in the genus Bacillus.     

The characterization and cloning of a gluconate (gnt) operon of Bacillus subtilis

The enzymes involved in gluconate utilization in Bacillus subtilis seemed to be gluconate permease and gluconate kinase. Several mutants unable to grow on gluconate were isolated. The mutations they harboured (gnt) were clustered between iol-6 and fdp-74 on the B. subtilis chromosome (a tentative map order of gnt-10, gnt-4, gnt-26, gnt-23 and gnt-9 was obtained). The gnt-10 mutation seemed to be located within the structural gene of the kinase, and the gnt-23 and gnt-26 mutations seemed to be within that of the permease. An EcoRI fragment (4.5 MDal) containing an intact gluconate (gnt) operon consisting of these two structural genes was cloned in phage phi 105 by prophage transformation and was mapped physically. The physical location of the mutations coincided with their order on the genetic map. The HindIII-A fragment (2.4 MDal), which corrects all the gnt mutations, was subcloned in plasmid pC194. The fragment contained the structural genes for the gluconate permease and kinase, but not the regulatory region of the gluconate operon.     

Control of the Ralstonia solanacearum Type III secretion system (Hrp) genes by the global virulence regulator PhcA

Expression of several virulence factors in the plant pathogen bacterium Ralstonia solanacearum is controlled by a complex regulatory network, at the center of which is PhcA. We provide genetic evidence that PhcA also represses the expression of hrp genes that code for the Type III protein secretion system, a major pathogenicity determinant in this bacterium. The repression of hrp genes in complete medium is relieved in a phcA mutant and two distinct signals, a quorum-sensing signal and complex nitrogen sources, appear to trigger this PhcA-dependent repression. This control of hrp gene expression by PhcA is realized at the level of the HrpG regulatory protein.     

Effect of mutations causing gluconate kinase or gluconate permease deficiency on expression of the Bacillus subtilis gnt operon.

The gluconate (gnt) operon contains genes for a repressor of the operon, gluconate kinase, and gluconate permease. A nonleaky kinase mutation (gntK4) induced the gnt operon constitutively through interaction of the repressor with an inducer of gluconate which had been endogenously formed and accumulated in the cell owing to the complete deficiency of the kinase even in the absence of gluconate in the medium. In contrast, a nonleaky permease mutation (gntP9) never induced the operon by gluconate likely because it cannot give rise to its inducing concentration in the cell even in the presence of gluconate in the medium.     

Identification of GntR as regulator of the glucose metabolism in Pseudomonas aeruginosa

In contrast to Escherichia coli, glucose metabolism in pseudomonads occurs exclusively through the Entner‐Doudoroff (ED) pathway. This pathway, as well as the three routes to generate the initial ED pathway substrate, 6‐phosphogluconate, is regulated by the PtxS, HexR and GtrS/GltR systems. With GntR (PA2320) we report here the identification of an additional regulator in Pseudomonas aeruginosa PAO1. GntR repressed its own expression as well as that of the GntP gluconate permease. In contrast to PtxS and GtrS/GltR, GntR did not modulate expression of the toxA gene encoding the exotoxin A virulence factor. GntR was found to bind to promoters P_gntR and P_gntP and the consensus sequence of its operator was defined as 5′‐AC‐N‐AAG‐N‐TAGCGCT‐3′. Both operator sites overlapped with the RNA polymerase binding site and we show that GntR employs an effector mediated de‐repression mechanism. The release of promoter bound GntR is induced by gluconate and 6‐phosphogluconate that bind with similar apparent affinities to the GntR/DNA complex. GntR and PtxS are paralogous and may have evolved from a common ancestor. The concerted action of four regulatory systems in the regulation of glucose metabolism in Pseudomonas can be considered as a model to understand complex regulatory circuits in bacteria.