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.

Gene expression and characterization of 2-keto-3-deoxy-gluconate kinase, a key enzyme in the modified Entner-Doudoroff pathway of Serratia marcescens KCTC 2172

We cloned 2-keto-3-deoxy-gluconate kinase (KDGK), which catalyzes the phosphorylation of 2-keto-3-deoxygluconate (KDG) to 2-keto-3-deoxy-6-phophogluconate (KDPG) from Serratia marcescens KCTC 2172. The nucleotide sequence revealed a single open reading frame containing 1,208 bp and encoding for 309 amino acids, with a molecular weight of 33,993 Da. The enzyme was purified via GST affinity chromatography. The putative KdgT binding site was detected upstream of the initial codon. The KDG kinase utilized 2-ketogluconate (KG) and KDG as substrates. The optimal temperature and pH for KDGK activity were 50ºC and 8.0, respectively.

Gluconate as suitable potential reduction supplier in Corynebacterium glutamicum: Cloning and expression of gntP and gntK in Escherichia coli

Corynebacterium glutamicum is widely used in the industrial production of amino acids. We have found that this bacterium grows exponentially on a mineral médium supplemented with gluconate. Gluconate permease and Gluconokinase are expressed in an inducible form and, 6-phosphogluconate dehydrogenase, although constituvely expressed, shows a 3-fold higher specific level in gluconate grown cells than those grown in fructose under similar conditions. Interestingly, these activities are lower than those detected in the strain Escherichia coli Ml-8, cultivated under similar conditions. Additionally, here we also confirmed that this bacterium lacks 6-phosphogluconate dehydratase activity. Thus, gluconate must be metabolized through the pentose phosphate pathway. Genes encoding gluconate transport and its phosphorylation were cloned from C. glutamicum, and expressed in suitable E. coli mutants. Sequence analysis revealed that the amino acid sequences obtained from these genes, denoted as gntP and gntK, were similar to those found in other bacteria. Analysis of both genes by RT-PCR suggested constitutive expression, in disagreement with the inducible character of their corresponding activities. The results suggest that gluconate might be a suitable source of reduction potential for improving the efficiency in cultures engaged in amino acids production. This is the first time that gluconate specific enzymatic activities are reported in C. glutamicum.

Optimisation of fermentation conditions for gluconic acid production by a mutant of Aspergillus niger.

Aspergillus niger ORS-4, isolated from the sugarcane industry waste materials was found to produce notable level of gluconic acid. From this strain, a mutant Aspergillus niger ORS-4.410 having remarkable increase in gluconic acid production was isolated and compared for fermentation properties. Among the various substrates used, glucose resulted into maximum production of gluconic acid (78.04 g/L). 12% concentration led to maximum production. Effect of spore age and inoculum level on fermentation indicated an inoculum level of 2% of the 4-7 days old spores were best suited for gluconic acid production. Maximum gluconate production could be achieved after 10-12 days of the fermentation at 30 degrees C and at a pH of 5.5. Kinetic analysis of production indicated that growth of the mutant was favoured during initial stages of the fermentation (4-8 days) and production increased during the subsequent 8-12 days of the fermentation. CaCO3 and varying concentrations of different nutrients affected the production of gluconic acid. Analysis of variance for the factors evaluated the significant difference in the production levels.

Gluconic acid production by Aspergillus niger mutant ORS-4.410 in submerged and solid state surface fermentation.

Aspergillus niger ORS-4.410, a mutant of Aspergillus niger ORS-4 was produced by repeated irradiation with UV rays. Treatments with chemical mutagnes also resulted into mutant strains. The mutants differed from the parent strain morphologically and in gluconic acid production. The relationship between UV treatment dosage, conidial survival and frequency of mutation showed the maximum frequency of positive mutants (25%) was obtained along with a conidial survival of 59% after second stage of UV irradiation. Comparison of gluconic acid production of the parent and mutant ORS-4.410 strain showed a significant increase in gluconic acid production that was 87% higher than the wild type strain. ORS-4.410 strain when transferred every 15 days and monitored for gluconic acid levels for a total period of ten months appeared stable. Mutant ORS-4.410 at 12% substrate concentration resulted into significantly higher i.e. 85-87 and 94-97% yields of gluconic acid under submerged and solid state surface conditions respectively. Further increase in substrate concentration appeared inhibitory. Maximum yield of gluconic acid was obtained after 6 days under submerged condition and decreased on further cultivation. Solid state surface culture condition on the other hand resulted into higher yield after 12 days of cultivation and similar levels of yields continued thereafter.

Effect of ammonium and nitrate ratio on glucose oxidase activity during gluconic acid fermentation by a mutant strain of Aspergillus niger.

Of the factors tested, the source and concentration of carbon and nitrogen in the medium exerted maximum effect on growth and acid production. Glucose (15%) and urea (0.14%) induced glucose oxidase synthesis and optimum yield of calcium gluconate. Potassium dihydrogen phosphate (0.2%) and magnesium sulphate (0.06%) stimulated glucose oxidase activity and calcium gluconate production. Borax at a concentration of 1.5 g/L induced maximum glucose oxidase and calcium gluconate production with increased glucose utilization.

Selection of lacZ operon fusions in genes of gluconate metabolism in E. coli: Characterization of A gntT::lacZ fusion / Selección de fusiones lacZ de operon en genes del metabolismo del gluconato en E.coli: Caracterización de una fusión gntT::lacZ

The initial steps involved in the utilization of gluconate by E.coli, its incorporation into the cell and susequent phosphorylation to gluconate 6-phosphate, conform two system that duplicate activities. These system, GntI and GntII, are specified by two sets of genes distinctly regulated and located respectively at the malA-asd (75 min) and fdp-valS (96 min) regions of the bacterial chromosome. The precence of duplicate activities in the metabolism of gluconates of E.coli, has made difficult the study of the expression and participation of the GntI and GntII system. In order to advance in these respec, the phage *placMu53 was used to select operon gnt::lacZ fusion in a E.coli strain (edd-zwf), (gnd-his), lac. Here we report the study of a gntT::lacZ fusion. This transductan allowed to differentiate the inducible expresion of the gntT and gntU genes. its characteristic, in agreement with previous report, support the central role of the gntT gene in this metabolism

Sobre las actividades involucradas en el catabolismo inicial del gluconato en Escherichia coli / On the activities involved in the initial gluconale catabolismo in Escherichia coli

Las características cinéticas del sistema GntII y de la gluconoquinasa termoresisteme del sistema GntI se investigaron en las mutantes C-177 y M4 de E. coli respectivamente. Un valos aproximado de Km para gluconato de 2 x 10-5 M fue mostrado para el transporte codificado por gntS (GntII), el cual resulta similar al especificado por gntT (GntI). Tanto el gluconato como el ATP mostraron cooperatividad en sus interacciones con las gluconoquinasas, suguiriendo un posible papel regulatorio para estas enzimas en el catabolismo del gluconato en E. coli. Valores de Ko.5 para gluconato de 9 x 10-5 M y 1.1 x 10-5 M fueron estimados para las gluconoquinasas termosensible y termoresistente respectivamente. Ambas enzimas mostraron valores similares de Ko.5 para ATP (5 x 10-5 M)