2-Keto-l-gulonic Acid Fermentation

A number of bacterial strains from type culture collections and natural sources were examined in their metabolic characteristics toward sorbitol and l-sorbose.

Paper chromatographic analyses of sorbitol and l-sorbose metabolites obtained from the cultures of various bacteria revealed that the organisms producing 2-keto-l-gulonic acid from sorbitol were merely found in the genera Acetobacter, Gluconobacter and Pseudomonas, whereas those producing the acid from l-sorbose were distributed in the twelve genera of bacteria: Acetobacter, Alcaligenes, Aerobacter, Azotobacter, Bacillus, Escherichia, Gluconobacter, Klebsiella, Micrococcus, Pseudomonas, Serratia and Xanthomonas.

G. melanogenus, which was characterized by excellent production of 2-keto-l-gulonic acid from sorbitol, also formed several other sugars and sugar acids as the sorbitol metabolites. These compounds were identified to be d-fructose, l-sorbose, d-mannonic acid, L-idonic acid, 2-keto-d-gluconic acid and 5-keto-d-mannonic acid, respectively, by means of two-dimensional paper chromatography.

Bacteria producing 2-keto-l-gulonic acid from sorbitol were usually isolated from fruits but not from soil.     

Polyol Dehydrogenases in the Soluble Fraction of Acetobacter melanogenum

Polyol dehydrogenases of Acetobacter melanogenum were investigated. Three polyol dehydrogenases, i. e. NAD⁺-linked d-mannitol dehydrogenase, NAD⁺-linked sorbitol dehydrogenase and NADP⁺-linked d-mannitol dehydrogenase, in the soluble fraction of the organism were purified 12-fold, 8-fold and 88-fold, respectively, by fractionation with ammonium sulfate and DEAE-cellulose column chromatography. NAD⁺-linked sorbitol dehydrogenase reduced 5-keto-d-fructose (5KF) to l-sorbose in the presence of NADH, whereas NADP⁺-linked d-mannitol dehydrogenase reduced the same substrate to d-fructose in the presence of NADPH. It was also shown that NAD⁺-linked d-mannitol dehydrogenase was specific for the interconversion between d-mannitol and d-fructose and that this enzyme was very unstable in alkaline conditions.     

2-Keto-l-gulonic Acid Fermentation

l-Sorbose metabolism in Pseudomonas aeruginosa IFO 3898 was studied. When the strain was cultivated in l-sorbose medium, l-idonic and 2-keto-l-gulonic acids were detected in the culture broth.

From the results on the metabolism of various sugars and sugar acids with the cell suspension and the metabolites accumulated, the following pathway was proposed for the l-sorbose metabolism in Ps. aeruginosa IFO 3898.

l-Sorbose → l-idose → l-idonic acid → 2-keto-l-gulonic acid.     

Isolation and Characterization of Thermotolerant Gluconobacter Strains Catalyzing Oxidative Fermentation at Higher Temperatures

Thermotolerant acetic acid bacteria belonging to the genus Gluconobacter were isolated from various kinds of fruits and flowers from Thailand and Japan. The screening strategy was built up to exclude Acetobacter strains by adding gluconic acid to a culture medium in the presence of 1% D-sorbitol or 1% D-mannitol. Eight strains of thermotolerant Gluconobacter were isolated and screened for D-fructose and L-sorbose production. They grew at wide range of temperatures from 10°C to 37°C and had average optimum growth temperature between 30-33°C. All strains were able to produce L-sorbose and D-fructose at higher temperatures such as 37°C. The 16S rRNA sequences analysis showed that the isolated strains were almost identical to G. frateurii with scores of 99.36-99.79%. Among these eight strains, especially strains CHM16 and CHM54 had high oxidase activity for D-mannitol and D-sorbitol, converting it to D-fructose and L-sorbose at 37°C, respectively. Sugar alcohols oxidation proceeded without a lag time, but Gluconobacter frateurii IFO 3264^T was unable to do such fermentation at 37°C. Fermentation efficiency and fermentation rate of the strains CHM16 and CHM54 were quite high and they rapidly oxidized D-mannitol and D-sorbitol to D-fructose and L-sorbose at almost 100% within 24 h at 30°C. Even oxidative fermentation of D-fructose done at 37°C, the strain CHM16 still accumulated D-fructose at 80% within 24 h. The efficiency of L-sorbose fermentation by the strain CHM54 at 37°C was superior to that observed at 30°C. Thus, the eight strains were finally classified as thermotolerant members of G. frateurii.     

Main Polyol Dehydrogenase of Gluconobacter suboxydans IFO 3255, Membrane-bound D-Sorbitol Dehydrogenase,That Needs Product of Upstream Gene,sldB, for Activity

The D-sorbitol dehydrogenase gene, sldA, and an upstream gene, sldB, encoding a hydrophobic polypeptide, SldB, of Gluconobacter suboxydans IFO 3255 were disrupted in a check of their biological functions. The bacterial cells with the sldA gene disrupted did not produce L-sorbose by oxidation of D-sorbitol in resting-cell reactions at pHs 4.5 and 7.0, indicating that the dehydrogenase was the main D-sorbitol-oxidizing enzyme in this bacterium. The cells did not produce D-fructose from D-mannitol or dihydroxyacetone from glycerol. The disruption of the sldB gene resulted in undetectable oxidation of D-sorbitol, D-mannitol, or glycerol, although the cells produced the dehydrogenase. The cells with the sldB gene disrupted produced more of what might be signal-unprocessed SldA than the wild-type cells did. SldB may be a chaperone-like component that assists signal processing and folding of the SldA polypeptide to form active D-sorbitol dehydrogenase.     

2-Keto-l-Gulonic Acid Fermentation

Fractionation of sorbitol metabolites in the culture liquid of Gluconobacter melanogenus IFO 3292 was examined by column chromatographic techniques. Ion exchange column chromatography of the culture supernatant allowed to divide the components of the metabolites into Fractions I, II, III and IV. Paperelectrophoretic and paperchromatographic analyses of these fractions revealed that Fractions I, II, III and IV contained neutral sugar, hexonic acids, 5-ketohexonic acid and 2-ketohexonic acids, respectively.

The neutral sugar in Fraction I, the 5-ketohexonic acid in Fraction III and the 2-ketohexonic acids in Fraction IV were isolated and determined to be l-sorbose, 5-keto-d- mannonic, 2-keto-d-gluconic and 2-keto-l-gulonic acids, respectively, from their physical properties. In Fraction II were contained two different hexonic acids, one of which was identified to be l-idonic acid by the aid of substrate specificity of a hexonic acid dehydrogenase of Pseudomonas aeruginosa, and the other was determined to be d-mannonic acid as the phenylhydrazide derivative.     

Biochemical Aspects of 2-Keto-l-gulonate Accumulation from 2,5-Diketo-d-gluconate by Corynebacterium sp. and Its Mutants

Corynebacterium sp. SHS 0007 accumulated 2-keto-l-gulonate and 2-keto-d-gluconate simultaneously with 2,5-diketo-d-gluconate utilization. This strain, however, possibly metabolized 2,5- diketo-d-gluconate through two pathways leading to d-gluconate as a common intermediate: via 2- keto-d-gluconate, and via 2-keto-l-gulonate, l-idonate and 5-keto-d-gluconate. A polysaccharide- negative, 2-keto-l-gulonate-negative and 5-keto-d-gluconate-negative mutant produced only calcium 2-keto-l-gulonate from calcium 2,5-diketo-d-gluconate, in a 90.5 mol% yield. The addition of a hydrogen donor such as d-glucose was essential for its production. This mutant possessed the direct oxidation route of d-glucose to d-gluconate, the pentose cycle pathway and a possible Embden-Meyerhof-Parnas pathway, indicating that d-glucose was metabolized through these three pathways and provided NADPH for the reduction of 2,5-diketo-d-gluconate.     

Distinct Physiological Roles of Two Membrane-Bound Dehydrogenases Responsible for D-Sorbitol Oxidation in Gluconobacter frateurii

Two different membrane-bound enzymes oxidizing D-sorbitol are found in Gluconobacter frateurii THD32: pyroloquinoline quinone-dependent glycerol dehydrogenase (PQQ-GLDH) and FAD-dependent D-sorbitol dehydrogenase (FAD-SLDH). In this study, FAD-SLDH appeared to be induced by L-sorbose. A mutant defective in both enzymes grew as well as the wild-type strain did, indicating that both enzymes are dispensable for growth on D-sorbitol. The strain defective in PQQ-GLDH exhibited delayed L-sorbose production, and lower accumulation of it, corresponding to decreased oxidase activity for D-sorbitol in spite of high D-sorbitol dehydrogenase activity, was observed. In the mutant strain defective in PQQ-GLDH, oxidase activity with D-sorbitol was much more resistant to cyanide, and the H⁺/O ratio was lower than in either the wild-type strain or the mutant strain defective in FAD-SLDH. These results suggest that PQQ-GLDH connects efficiently to cytochrome bo ₃ terminal oxidase and that it plays a major role in L-sorbose production. On the other hand, FAD-SLDH linked preferably to the cyanide-insensitive terminal oxidase, CIO.     

Protective Actions of l-Aspartate from Acid or Proteolytic Inactivation

1. l-Aspartate was found to replace l-asparagine in the protective action from acid inactivation of l-asparaginase (EC 3.5.1.1) produced by Escherichia coli A–1–3 and at the same time to inhibit the proteolytic inactivation by α-chymotrypsin.

2. l-Asparaginase changed in its chromatographic properties in the presence of l-aspartate and became to be absorbed on the CM Sephadex column.

3. The sedimentation patterns of l-asparaginase at pH 3.5 were identical either in the presence or absence of l-aspartate, showing partial dissociation. But the reversibility to the active state was observed only in the enzyme dissolved in the solution containing l-aspartate.

4. l-Aspartate did not prevent the enzyme either from the dissociation into subunits or from decrease in the activity by urea.

5. High concentration of l-aspartate was shown to inhibit the l-asparagine hydrolysis reaction.

6. l-Aspartate was suggested from ORD measurements to cause changes in the higher structure as well as the ionic properties or proteolytic inactivation.

     

Enzyme-Substrate Complex of p-Hydroxybenzoate Hydroxylase; One of the Activated Intermediates of the Overall Reaction

The transglucosidation reaction of brewer’s yeast α-glucosidase was examined under the co-existence of l-sorbose and phenyl-α-glucoside. As the transglucosidation products, three kinds of new disaccharide were chromatographically isolated. It was presumed that these disaccharides consisting of d-glucose and l-sorbose were 1-O-α-d-glucopyranosyl-l-sorbose ([α]_D+89.0), 3-O-α-d-glucopyranosyl-l-sorbose ([α]_D+69.1) and 4-O-α-d-glucopyranosyl-l-sorbose ([α]_D+81.0). The principal product formed in the enzyme reaction was 1-O-α-d-glucopyranosyl-l-sorbose.     

Separation of l-Leucine-pyruvate and l-Leucine-α-ketoglutarate Transaminases in Acetobacter suboxydans and Identification of Their Reaction Products

l-Leucine-pyruvate and l-leucine-α-ketoglutarate(α-KGA) transaminases were separated by DEAE-cellulose column chromatography and partially purified to 200- and 50-fold, respectively, from the cell-free extract of Acetobacter suboxydans (Gluconobacter suboxydans IFO 3172). The optimum pH range of the former was 5.0~5.5 and that of the latter was 8.5~9.0. l-Leucine, l-citrulline, and l-methionine were the most effective amino donors for the l-leucine-pyruvate transaminase. Basic amino acids as well as aromatic amino acids were able to be amino donors for the transamination with pyruvate. α-KGA was effective as an amino acceptor for this enzyme. The l-leucine-α-KGA transaminase had the typical properties of the branched-chain amino acid transaminase in its substrate specificity.

The reaction products of the transaminations were identified. l-Alanine was formed from pyruvate and l-glutamate from α-KGA. α-Keto acids formed from various amino acids by the l-leucine-pyruvate transaminase were also identified.     

Conformation of Some Hexuronic Acids and d-Galactopyranosiduronic Acid Moiety in the Peracetylated and Permethylated Derivatives of Orange Pectic Acid in Solutions

1. The 1C conformation was estimated for α-d-galactopyranosiduronic acid moiety of pectic acid in the permethylated derivative dissolved in 1 n NaOD-D₂O and in the peracetylated derivative dissolved in dimethyl sulfoxide-d₆, and the C1 conformation was estimated for some derivatives of d-galactopyranuronic acid in chloroform-d by NMR spectroscopy.

2. Random conformation of the whole macromolecule was estimated for pectic acid in water on the basis of no appearance of any induced Cotton effects in the 200 ~ 700 mμ region in the ORD spectra of pectic acid-anionic dye complexes.

3. The conformation was supported by the fact that the rate of periodate oxidation of pectic acid at 5° was slightly decreased in comparison with that of amylase in 7 m urea solution.

     

Biochemical characteristics of maltose phosphorylase MalE from Bacillus sp. AHU2001 and chemoenzymatic synthesis of oligosaccharides by the enzyme

ABSTRACT

Maltose phosphorylase (MP), a glycoside hydrolase family 65 enzyme, reversibly phosphorolyzes maltose. In this study, we characterized Bacillus sp. AHU2001 MP (MalE) that was produced in Escherichia coli. The enzyme exhibited phosphorolytic activity to maltose, but not to other α-linked glucobioses and maltotriose. The optimum pH and temperature of MalE for maltose-phosphorolysis were 8.1 and 45°C, respectively. MalE was stable at a pH range of 4.5–10.4 and at ≤40°C. The phosphorolysis of maltose by MalE obeyed the sequential Bi–Bi mechanism. In reverse phosphorolysis, MalE utilized d-glucose, 1,5-anhydro-d-glucitol, methyl α-d-glucoside, 2-deoxy-d-glucose, d-mannose, d-glucosamine, N-acetyl-d-glucosamine, kojibiose, 3-deoxy-d-glucose, d-allose, 6-deoxy-d-glucose, d-xylose, d-lyxose, l-fucose, and l-sorbose as acceptors. The k_cat(app)/K_m(app) value for d-glucosamine and 6-deoxy-d-glucose was comparable to that for d-glucose, and that for other acceptors was 0.23–12% of that for d-glucose. MalE synthesized α-(1→3)-glucosides through reverse phosphorolysis with 2-deoxy-d-glucose and l-sorbose, and synthesized α-(1→4)-glucosides in the reaction with other tested acceptors.     

Detection of Carboxymethyl Cellulase Activity in Acetobacter xylinum KU-1

We detected carboxymethyl cellulase activity in a crude extract of Acetobacter xylinum KU-1. The enzyme activity was detected when glycerol, d-fructose, d-mannitol, d-glucose, d-arabitol, d-sorbitol, or carboxymethyl cellulose was used as a carbon source. The optimum pH was found to be 4.0, while the optimum temperature was 50°C. The enzyme activity was inhibited characteristically by the addition of Hg²⁺.     

Desalting DNA by Drop Dialysis Increases Library Size upon Transformation

D-Mannitol dehydrogenase (EC 1.1.1.138) was purified and crystallized for the first time from the cell-free extract of Gluconobacter suboxydans IFO 12528. The enzyme was purified about 100-fold by a procedure involving ammonium sulfate fractionation, DEAE-Sephadex A-50 column chromatography, and gel filtration by a Sephadex G-75 column. The enzyme was completely separated from a similar enzyme, NAD-dependent D-mannitol dehydrogenase (EC 1.1.1.67), during enzyme purification. There being sufficient purity of the enzyme at this stage, the enzyme was crystallized, by the addition of ammonium sulfate, to fine needles. The crystalline enzyme showed a single sedimentation peak in analytical ultracentrifugation, giving an apparent sedimentation constant of 3.6 s. The molecular mass of the enzyme was estimated to be 50 kDa by SDS-PAGE and gel filtration chromatography. Oxidation of D-mannitol to D-fructose and reduction of D-fructose to D-mannitol were specifically catalyzed with NADP and NADPH, respectively. NAD and NADH were inert for the enzyme. Since the reaction equilibrium declined to D-fructose reduction over a wide pH range, the enzyme showed several advantages for direct enzymatic measurement of D-fructose. Even in the presence of a large excess of D-glucose and other substances, oxidation of NADPH to NADP was highly specific and stoichiometric to the D-fructose reduced.     

Effects of Acetylation with Acetic Anhydricle

1. L-Asparaginase (EC 3.5.1.1) from Escherichia coli A–l–3 was acetylated using acetic anhydride as a modifying chemical. The fully acetylated L-asparaginase retained 60% of the activity of the unmodified L-asparaginase.

2. The acetylated L-asparaginase hydrolyzed D-asparagine and L-glutamine as well as L-asparagine in the same ratio as the unmodified L-asparaginase did.

3. However, the effects of pH on the activity of the acetylated L-asparaginase showed very interesting differences from that of L-asparaginase. On the other hand, both L-asparaginase and the acetylated L-asparaginase exhibited similar pH activity curves on L-glutamine hydrolysis.

4. The acetylated L-asparaginase was found to become more stable against acid or heat in the presence of L-aspartate than in its absence in the same manner as L-asparaginase was.

     

A pyrroloquinoline quinine-dependent membrane-bound d-sorbitol dehydrogenase from Gluconobacter oxydans exhibits an ordered Bi Bi reaction mechanism

A membrane-bound pyrroloquinoline quinine (PQQ)-dependent d-sorbitol dehydrogenase (mSLDH) in Gluconobacter oxydans participates in the oxidation of d-sorbitol to l-sorbose by transferring electrons to ubiquinone which links to the respiratory chain. To elucidate the kinetic mechanism, the enzyme purified was subjected to two-substrate steady-state kinetic analysis, product and substrate inhibition studies. These kinetic data indicate that the catalytic reaction follows an ordered Bi Bi mechanism, where the substrates bind to the enzyme in a defined order (first ubiquinone followed by d-sorbitol), while products are released in sequence (first l-sorbose followed by ubiquinol). From these findings, we proposed that the native mSLDH bears two different substrate-binding sites, one for ubiquinone and the other for d-sorbitol, in addition to PQQ-binding and Mg²⁺-binding sites in the catalytic center.     

Studies on the Formation of the Cheese-like Flavor

Solution containing l-leucine and l-methionine cultured by Aspergillus flavus were found to develop cheese-like flavor.

α-Keto-isocaproic acid was isolated and identified from the culture of l-leucine and α-keto-β-methylmercaptobutyric acid from that of l-methionine. The flavor was also developed from the mixture of the synthetic sample of α-ketoisocaproic acid and α-keto-β-methylmercaptobutyric acid.     

Crystalline d-Mannitol:NAD Oxidoreductase from Leuconostoc mesenteroides

The crystalline d-mannitol dehyrogenase (d-mannitol:NAD oxidoreductase, EC 1.1.1.67) catalyzed the reversible reduction of d-fructose to d-mannitol. d-Sorbitol was oxidized only at the rate of 4% of the activity for d-mannitol. The enzyme was inactive for all of four pentitols and their corresponding 2-ketopentoses. The apparent optimal pH for the reduction of d-fructose or the oxidation of d-mannitol was 5.35 or 8.6, respectively. The Michaelis constants were 0.035 m for d-fructose and 0.020 m for d-mannitol. The enzyme was also found to be specific for NAD. The Michaelis constans were 1 × 10^?5 m for NADH₂ and 2.7 × 10^?4 m for NAD.     

d-Gluconate Dehydrogenase, 2-Keto-d-gluconate Yielding,from Gluconobacter dioxyacetonicus: Purification and Characterization

d-Gluconate dehydrogenase catalyzing the oxidation of d-gluconate to 2-keto-d-gluconate was solubilized with Triton X-100 from the membrane of Gluconobacter dioxyacetonicus IFO 3271 and purified to an almost homogeneous state by chromatographies on DEAE-cellulose and CM-Toyopearl in the presence of 0.1% Triton X-100. The enzyme had three subunits with molecular weights of 64,000, 45,000 and 21,000, and contained approximately 2 mol of heme per mol of the enzyme. The prosthetic group of the dehydrogenase was found to be a flavin covalently bound to the enzyme protein. The substrate specificity of the purified enzyme was very strict for d-gluconate and the apparent Michaelis constant for d-gluconate was 2.2 mm. The optimum pH and temperature of the purified enzyme were 6.0 and 40°C, respectively.