Simultaneous utilization of D-cellobiose, D-glucose, and D-xylose by recombinant Corynebacterium glutamicum under oxygen-deprived conditions

Corynebacterium glutamicum R was metabolically engineered to broaden its sugar utilization range to d-xylose and d-cellobiose contained in lignocellulose hydrolysates. The resultant recombinants expressed Escherichia coli xylA and xylB genes, encoding d-xylose isomerase and xylulokinase, respectively, for d-xylose utilization and expressed C. glutamicum R bglF ^317A and bglA genes, encoding phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) β-glucoside-specific enzyme IIBCA component and phospho-β-glucosidase, respectively, for d-cellobiose utilization. The genes were fused to the non-essential genomic regions distributed around the C. glutamicum R chromosome and were under the control of their respective constitutive promoter trc and tac that permitted their expression even in the presence of d-glucose. The enzyme activities of resulting recombinants increased with the increase in the number of respective integrated genes. Maximal sugar utilization was realized with strain X5C1 harboring five xylA–xylB clusters and one bglF ^317A –bglA cluster. In both d-cellobiose and d-xylose utilization, the sugar consumption rates by genomic DNA-integrated strain were faster than those by plasmid-bearing strain, respectively. In mineral medium containing 40 g l⁻¹ d-glucose, 20 g l⁻¹ d-xylose, and 10 g l⁻¹ d-cellobiose, strain X5C1 simultaneously and completely consumed these sugars within 12 h and produced predominantly lactic and succinic acids under growth-arrested conditions.     

Production of d-hydantoinase by halophilic Pseudomonas sp. NCIM 5109

About 1000 bacterial colonies isolated from sea water were screened for their ability to convert dl-5-phenylhydantoin to d(−)N-carbamoylphenylglycine as a criterion for the determination of hydantoinase activity. The strain M-1, out of 11 hydantoinase-producing strains, exhibited the maximum ability to convert dl-5-phenylhydantoin to d(−)N-carbamoylphenylglycine. The strain M-1 appeared to be a halophilic Pseudomonas sp. according to morphological and physiological characteristics. Optimization of the growth parameters revealed that nutrient broth with 2% NaCl was the preferred medium for both biomass and enzyme production. d-Hydantoinase of strain M-1 was not found to be inducible by the addition of uracil, dihydrouracil, β-alanine etc. The optimum temperature for enzyme production was about 25 °C and the organism showed a broad pH optimum (pH 6.5–9.0) for both biomass and hydantoinase production. The organism seems to have a strict requirement of NaCl for both growth and enzyme production. The optimum pH and temperature of enzyme activity were 9–9.5 and 30 °C respectively. The biotransformation under the alkaline conditions allowed the conversion of 80 g l⁻¹ dl-5-phenylhydantoin to 82 g l⁻¹ d(−)N-carbamoylphenylglycine within 24 h with a molar yield of 93%. Received: 15 September 1997 / Received revision: 5 January 1998 / Accepted: 6 January 1998     

Isolation and characterization of a d-glucose/xylose isomerase from a new thermophilic strain Streptomyces sp. (PLC)

A thermostable d-xylase isomerase from a newly isolated thermophilic Streptomyces sp. (PLC) strain is described. The enzyme was purified to homogeneity. It is a homotetramer with a native molecular mass of 183 kDa and a subunit molecular mass of 46 kDa. The enzyme has a K _m of 35 mM for d-xylose and also accepts d-glucose as substrate, however, with a tenfold higher K _m (0.4 M) and half the maximum velocity. Both the activity and stability of this d-xylose isomerase depend strongly on divalent metal ions. Two metal ions bind per subunit to non-identical sites. Mg²⁺, Mn²⁺ and Co²⁺ are of comparable efficiency for the d-xylose isomerase reaction. Con²⁺ is the most efficient cofactor for d-glucose isomerization. The enzyme remains fully active up to 95°C. The activity decreases at 53°C in the presence of Co²⁺ and Mg²⁺ with a half-life of 7 and 9 days respectively. In the presence of Mn²⁺ the enzyme activity remains constant for at least 10 days and at 70°C 50% of the activity is lost after 5 days.     

Characterization of Enzymes in the Oxidation of 1,2-Propanediol to <Emphasis Type="SmallCaps">d</Emphasis>-(−)-Lactic Acid by <Emphasis Type="Italic">Gluconobacter oxydans</Emphasis> DSM 2003

Although Gluconobacter oxydans can convert 1,2-propanediol to d-(−)-lactic acid, the enzyme(s) responsible for the conversion has remain unknown. In this study, the membrane-bound alcohol dehydrogenase (ADH) of Gluconobacter oxydans DSM 2003 was purified and confirmed to be essential for the process of d-(−)-lactic acid production by gene knockout and complementation studies. A 25 percent decrease in d-(−)-lactic acid production was found for the aldehyde dehydrogenase (ALDH) deficient strain of G. oxydans DSM 2003, indicating that this enzyme is involved in the reaction but not necessary. It is the first report that reveals the function of ADH and ALDH in the biooxidation of 1,2-propanediol to d-(−)-lactic acid by G. oxydans DSM 2003.     

Degradation of rice bran hemicellulose by <Emphasis Type="Italic">Paenibacillus</Emphasis> sp. strain HC1: gene cloning,characterization and function of β-D-glucosidase as an enzyme involved in degradation

A bacterium (strain HC1) capable of assimilating rice bran hemicellulose was isolated from a soil and identified as belonging to the genus Paenibacillus through taxonomical and 16S rDNA sequence analysis. Strain HC1 cells grown on rice bran hemicellulose as a sole carbon source inducibly produced extracellular xylanase and intracellular glycosidases such as β-d-glucosidase and β-d-arabinosidase. One of them, β-d-glucosidase was further analyzed. A genomic DNA library of the bacterium was constructed in Escherichia coli and gene coding for β-d-glucosidase was cloned by screening for β-d-glucoside-degrading phenotype in E. coli cells. Nucleotide sequence determination indicated that the gene for the enzyme contained an open reading frame consisting of 1,347 bp coding for a polypeptide with a molecular mass of 51.4 kDa. The polypeptide exhibits significant homology with other bacterial β-d-glucosidases and belongs to glycoside hydrolase family 1. β-d-Glucosidase purified from E. coli cells was a monomeric enzyme with a molecular mass of 50 kDa most active at around pH 7.0 and 37°C. Strain HC1 glycosidases responsible for degradation of rice bran hemicellulose are expected to be useful for structurally determining and molecularly modifying rice bran hemicellulose and its derivatives.     

Xylose metabolism in the anaerobic fungus<Emphasis Type="Italic"> Piromyces</Emphasis> sp. strain E2 follows the bacterial pathway

The anaerobic fungus Piromyces sp. strain E2 metabolizes xylose via xylose isomerase and d-xylulokinase as was shown by enzymatic and molecular analyses. This resembles the situation in bacteria. The clones encoding the two enzymes were obtained from a cDNA library. The xylose isomerase gene sequence is the first gene of this type reported for a fungus. Northern blot analysis revealed a correlation between mRNA and enzyme activity levels on different growth substrates. Furthermore, the molecular mass calculated from the gene sequence was confirmed by gel permeation chromatography of crude extracts followed by activity measurements. Deduced amino acid sequences of both genes were used for phylogenetic analysis. The xylose isomerases can be divided into two distinct clusters. The Piromyces sp. strain E2 enzyme falls into the cluster comprising plant enzymes and enzymes from bacteria with a low G+C content in their DNA. The d-xylulokinase of Piromyces sp. strain E2 clusters with the bacterial d-xylulokinases. The xylose isomerase gene was expressed in the yeast Saccharomyces cerevisiae, resulting in a low activity (25±13 nmol min^–1mg protein^-1). These two fungal genes may be applicable to metabolic engineering of Saccharomyces cerevisiae for the alcoholic fermentation of hemicellulosic materials.     

d-Xylose isomerases from a newly isolated strain, Paenibacillus sp., and from Alcaligenes ruhlandii : isolation, characterization and immobilisation to solid supports

d-Xylose/d-glucose isomerases from two strains, a newly isolated strain, Paenibacillus sp., and from Alcaligenes ruhlandii are described herein. The enzymes were purified to apparent homogeneity. Both of these d-xylose isomerases are homotetramers with relative subunit molecular masses of 45 000 and 53 000, respectively, as estimated by sodium dodecylsulphate-polyacrylamide gel electrophoresis. The native molecular masses determined on Superose 12 gel chromatography are 181 kDa for the enzyme from Paenibacillus sp. and 199 kDa for that from A. ruhlandii. The activity of both enzymes shows a requirement for divalent metal ions; the d-xylose isomerase from Paenibacillus sp. has the highest activity with Mn²⁺, while the enzyme from A. ruhlandii prefers Mg²⁺. Both enzymes also accept Co²⁺ with a somewhat lower efficiency, while Cu²⁺ inhibits the enzyme reaction. The binding of the metal ions obeys a biphasic characteristic, indicating the presence of two non-identical binding sites per subunit. d-Glucose is converted to d-fructose at a rate that is two- to three-fold slower than for the d-xylose isomerisation. d-Xylitol and d-lyxose are competitive inhibitors of both enzymes. Both enzymes have a pH optimum between 6.5 and 7.0, and they are active up to 60 °C. The enzyme from Paenibacillus sp. retained 50% of its activity after 4 days at 55 °C, whereas that from A. ruhlandii still retained 50% of its activity after 6 days at 55 °C. Polyacrylamide entrapment and immobilisation to both controlled pore glass and cyanogen-bromide-activated Sepharose were achieved for both enzymes with high efficiency. Received: 14 May 1998 / Received last revision: 29 July 1998 / Accepted: 29 July 1998     

d-Pentose metabolism byBacteroides vulgatus strain 8482

Bacteroides vulgatus strain 8482 metabolizedd-arabinose by a mechanism involving a 32 (top to bottom) cleavage of the arabinose carbon skeleton. During growth in the presence of 1-¹⁴C-d-arabinose, acetate, propionate, and succinate were labeled, but during growth in the presence of 5-labeledd-arabinose, only labeled acetate and succinate were formed. The metabolism ofd-ribose by strain 8482 differed from that ford-arabinose. Strain 8482 converted glycolic acid and glycine to acetate and succinate, but not propionate, by a mechanism involving cleavage of the glycine and glycolic acid carbon skeletons and equilibration of carbons 1 and 2 of glycolic acid and glycine with nonequivalent metabolic pools. The metabolism ofd-arabinose,d-ribose,d-glycine, andd-glycolic acid by strain 8482 was similar, in some respects, to that ofBacteroides fragilis strain 2044, but differed substantially from the metabolism of the same substances byBacteroides ruminicola strain B₁4.     

Isolation of a new cellulase gene from a thermophilic anaerobe and its expression inEscherichia coli

Summary A new cellulase gene was cloned and expressed inEscherichia coli from a thermophilic anaerobe, strain NA10. A 7.4 kbEcoRI fragment of NA10 DNA encoded the cellulase which hydrolyzed carboxymethyl cellulose, lichenan, andp-nitrophenyl--d-cellobioside, but could not digest laminarin andp-nitrophenyl--d-glucoside. The cloned enzyme could digest cellooligosaccharides and release cellobiose as a main product from cellotetraose but could not digest cellobiose. It was distinct from the endoglucanase which was cloned by us previously from NA10 strain in terms ofp-nitrophenyl--d-cellobioside degradation activity and the location of restriction enzyme sites. The enzyme produced byE. coli transformant was extremely heat-stable and the optimum temperature for the enzymatic reaction was 80°C. Fifty three percent of the cloned enzyme was detected in the periplasm and the remaining activity existed in the cellular fraction in theE. coli transformant.     

Enzymatic properties of the glycine d-alanine aminopeptidase of <Emphasis Type="Italic">Aspergillus oryzae</Emphasis> and its activity profiles in liquid-cultured mycelia and solid-state rice culture (rice koji)

The gdaA gene encoding S12 family glycine–d-alanine aminopeptidase (GdaA) was found in the industrial fungus Aspergillus oryzae. GdaA shares 43% amino acid sequence identity with the d-aminopeptidase of the Gram-negative bacterium Ochrobactrum anthropi. GdaA purified from an A. oryzae gdaA-overexpressing strain exhibited high d-stereospecificity and efficiently released N-terminal glycine and d-alanine of substrates in a highly specific manner. The optimum pH and temperature were 8 to 9 and 40°C, respectively. This enzyme was stable under alkaline conditions at pH 8 to 11 and relatively resistant to acidic conditions until pH 5.0. The chelating reagent EDTA, serine protease inhibitors such as AEBSF, benzamidine, TPCK, and TLCK, and the thiol enzyme inhibitor PCMB inhibited the enzyme. The aminopeptidase inhibitor bestatin did not affect the activity. GdaA was largely responsible for intracellular glycine and d-alanine aminopeptidase activities in A. oryzae during stationary-phase growth in liquid media. In addition, the activity increased in response to the depletion of nitrogen or carbon sources in the growth media, although the GdaA-independent glycine aminopeptidase activity highly increased simultaneously. Aminopeptidases of A. oryzae attract attention because the enzymatic release of a variety of amino acids and peptides is important for the enhancement of the palatability of fermented foods. GdaA activity was found in extracts of a solid-state rice culture of A. oryzae (rice koji), which is widely used as a starter culture for Japanese traditional fermented foods, and was largely responsible for the glycine and d-alanine aminopeptidase activity detected at a pH range of 6 to 9.     

d-2-hydroxyisocaproate dehydrogenase from Lactobacillus casei

Summary The new enzyme d-2-hydroxyisocaproate dehydrogenase (NAD⁺-dependent) was detected in strains of the genus Lactobacillus and related genera. Straight and branched chain aliphatic as well as aromatic 2-ketocarboxylic acids are stereospecifically reduced to the corresponding d-2-hydroxycarboxylic acids according to the following equation:R-CO-COOH + NADH + H⁺ R-CHOH-COOH + NAD⁺ The enzyme is called d-hydroxyisocaproate dehydrogenase by us because 2-ketoisocaproate is the substrate with the lowest K_M-value. NAD(H) as a cofactor cannot be replaced by NADP(H). Because of its broad substrate specificity we chose the strain Lactobacillus casei ssp. pseudoplantarum (DSM 20 008) for enzyme production and characterization. d-2-hydroxyisocaproate dehydrogenase could be purified 180-fold starting with 500 g of wet cells.The purification procedure involved liquid-liquid extraction with aqueous two-phase systems and ion-exchange chromatography. At this stage the enzyme has a specific activity of 25 U/mg and can be used for technical applications. Further purification up to a homogeneous protein with a specific activity of 110 U/mg can be achieved by chromatography on Amberlite CG 50 at pH 3.5. Properties important for technical application of the d-HicDH were investigated, especially the substrate specificity and the optimum pH- and temperature ranges for activity and stability of the catalist.     

A cDNA encoding 3-deoxy-d-manno-oct-2-ulosonate-8-phosphate synthase of Pisum sativum L. (pea) functionally complements a kdsA mutant of the Gram-negative bacterium Salmonella enterica

Recombinant plasmids encoding 3-deoxy-d-manno-oct-2-ulosonate-8-phosphate (Kdo-8-P) synthase (KdsA; EC 4.1.2.16) were identified from a cDNA library of Pisum sativum L. (pea) by complementing a temperature-sensitive kdsA ^ts mutant of the Gram-negative bacterium Salmonella enterica. Sequence analysis of several inserts revealed a central open reading frame encoding a protein of 290 amino acids with a high degree of amino acid sequence similarity to bacterial KdsA. The cDNA was confirmed by amplifying a 1,812-bp DNA fragment from the chromosome of pea that encoded four exons around the 5′-end of kdsA. The recombinant enzyme was subcloned, overexpressed and characterized to synthesize Kdo-8-P from d-arabinose-5-phosphate and phosphoenolpyruvate. The pH optimum was 6.1 and the activity of the enzyme was neither stimulated by the addition of divalent cations nor inhibited by EDTA. The cDNA of kdsA could not complement Escherichia coli K-12 strain AB3257, which is defective in all three isoenzymes (AroFGH) of 3-deoxy-d-arabino-hept-2-ulosonate-7-phosphate (Dha-7-P) synthase (EC 4.1.2.15), and neither d-erythrose-4-phosphate nor d-ribose-5-phosphate could substitute for d-arabinose-5-phosphate in vitro. Thus, plant cells possess a specific enzyme for the biosynthesis of Kdo-8-P with remarkable structural and functional similarities to bacterial KdsA proteins. Received: 14 July 2000 / Accepted: 30 August 2000     

Gene cloning and characterization of glycine oxidase from newly isolated <Emphasis Type="Italic">Bacillus subtilis</Emphasis> strain R5

The gene encoding the glycine oxidase from Bacillus subtilis strain R5 (goxR) was cloned and expressed in Escherichia coli. The gene consisted of 1,110 nucleotides that encoded a protein (GoxR) of 369 amino acid residues with a molecular mass of 40,761 Da. The GoxR exhibited 98.6% identity with glycine oxidase from B. subtilis strain 168. Gene expression and purification of the recombinant GoxR were performed. The recombinant GoxR existed in a homotetramer form. The recombinant protein effectively catalyzed the oxidation of glycine and d-alanine. The specific activity of the purified recombinant GoxR was 0.96 U/mg when glycine was used as a substrate and 1.0 U/mg when d-alanine was substrate. The enzyme displayed its highest activity at pH 8.0 and at a temperature of 50°C. The activation energy of the reaction catalyzed by the enzyme was calculated to be 26 kJ/mol. The enzyme activity was significantly inhibited in the presence of organic solvents. No enhancement of enzyme activity was observed in the presence of metal cations. The experimental results presented in this study demonstrate that the enzyme was a bonafide glycine oxidase.     

Characterization of a recombinant thermostable D-lyxose isomerase from Dictyoglomus turgidum that produces D-lyxose from D-xylulose

A putative d-lyxose isomerase from Dictyoglomus turgidum was purified with a specific activity of 19 U/mg for d-lyxose isomerization by heat treatment and affinity chromatography. The native enzyme was estimated as a 42 kDa dimer by gel-filtration chromatography. The activity of the enzyme was highest for d-lyxose, suggesting that it is a d-lyxose isomerase. The maximum activity of the enzyme was at pH 7.5 and 75°C in the presence of 0.5 mM Co²⁺, with a half-life of 108 min, K _m of 39 mM, and k _cat of 3,570 1/min. The enzyme is the most thermostable d-lyxose isomerase among those characterized to date. It converted 500 g d-xylulose/l to 380 g d-lyxose/l after 2 h. This is the highest concentration and productivity of d-lyxose reported thus far.     

Biochemical and molecular characterisation of the 2,3-dichloro-1-propanol dehalogenase and stereospecific haloalkanoic dehalogenases from a versatile <Emphasis Type="Italic">Agrobacterium</Emphasis> sp.

We previously reported the presence of both haloalcohol and haloalkanoate dehalogenase activity in the Agrobacterium sp. strain NHG3. The versatile nature of the organism led us to further characterise the genetic basis of these dehalogenation activities. Cloning and sequencing of the haloalcohol dehalogenase and subsequent analysis suggested that it was part of a highly conserved catabolic gene cluster. Characterisation of the haloalkanoate dehalogenase enzyme revealed the presence of two stereospecific enzymes with a narrow substrate range which acted on d -2-chloropropionic and I-2-chloropropionoic acid, respectively. Cloning and sequencing indicated that the two genes were separated by 87 bp of non-coding DNA and were preceded by a putative transporter gene 66 bp upstream of the d-specific enzyme.     

Biological nitrogen and organic matter removal from tannery wastewater in pilot plant operations in Ethiopia

A whole-cell biotransformation system for the conversion of d-fructose to d-mannitol was developed in Escherichia coli by constructing a recombinant oxidation/reduction cycle. First, the mdh gene, encoding mannitol dehydrogenase of Leuconostoc pseudomesenteroides ATCC 12291 (MDH), was expressed, effecting strong catalytic activity of an NADH-dependent reduction of d-fructose to d-mannitol in cell extracts of the recombinant E. coli strain. By contrast whole cells of the strain were unable to produce d-mannitol from d-fructose. To provide a source of reduction equivalents needed for d-fructose reduction, the fdh gene from Mycobacterium vaccae N10 (FDH), encoding formate dehydrogenase, was functionally co-expressed. FDH generates the NADH used for d-fructose reduction by dehydrogenation of formate to carbon dioxide. These recombinant E. coli cells were able to form d-mannitol from d-fructose in a low but significant quantity (15 mM). The introduction of a further gene, encoding the glucose facilitator protein of Zymomonas mobilis (GLF), allowed the cells to efficiently take up d-fructose, without simultaneous phosphorylation. Resting cells of this E. coli strain (3 g cell dry weight/l) produced 216 mM d-mannitol in 17 h. Due to equimolar formation of sodium hydroxide during NAD⁺-dependent oxidation of sodium formate to carbon dioxide, the pH value of the buffered biotransformation system increased by one pH unit within 2 h. Biotransformations conducted under pH control by formic-acid addition yielded d-mannitol at a concentration of 362 mM within 8 h. The yield Y _{D-mannitol/D-fructose}was 84 mol%. These results show that the recombinant strain of E. coli can be utilized as an efficient biocatalyst for d-mannitol formation.     

Properties of recombinant <Emphasis Type="Italic">Strep</Emphasis>-tagged and untagged hyperthermophilic D-arabitol dehydrogenase from <Emphasis Type="Italic">Thermotoga maritima</Emphasis>

The first hyperthermophilic d-arabitol dehydrogenase from Thermotoga maritima was heterologously purified from Escherichia coli. The protein was purified with and without a Strep-tag. The enzyme exclusively catalyzed the NAD(H)-dependent oxidoreduction of d-arabitol, d-xylitol, d-ribulose, or d-xylulose. A twofold increase of catalytic rates was observed upon addition of Mg²⁺ or K⁺. Interestingly, only the tag-less protein was thermostable, retaining 90% of its activity after 90 min at 85 °C. However, the tag-less form of d-arabitol dehydrogenase had similar kinetic parameters compared to the tagged enzyme, demonstrating that the Strep-tag was not deleterious to protein function but decreased protein stability. A single band at 27.6 kDa was observed on SDS-PAGE and native PAGE revealed that the protein formed a homohexamer and a homododecamer. The enzyme catalyzed oxidation of d-arabitol to d-ribulose and therefore belongs to the class of d-arabitol 2-dehydrogenases, which are typically observed in yeast and not bacteria. The product d-ribulose is a rare ketopentose sugar that has numerous industrially applications. Given its thermostability and specificity, d-arabitol 2-dehydrogenase is a desirable biocatalyst for the production of rare sugar precursors.     

Enzymatic conversion of D-galactose to D-tagatose: heterologous expression and characterisation of a thermostable L-arabinose isomerase from Thermoanaerobacter mathranii

The ability to convert d-galactose into d-tagatose was compared among a number of bacterial l-arabinose isomerases (araA). One of the most efficient enzymes, from the anaerobic thermophilic bacterium Thermoanaerobacter mathranii, was produced heterologously in Escherichia coli and characterised. Amino acid sequence comparisons indicated that this enzyme is only distantly related to the group of previously known araA sequences in which the sequence similarity is evident. The substrate specificity and the Michaelis–Menten constants of the enzyme determined with l-arabinose, d-galactose and d-fucose also indicated that this enzyme is an unusual, versatile l-arabinose isomerase which is able to isomerise structurally related sugars. The enzyme was immobilised and used for production of d-tagatose at 65 °C. Starting from a 30% solution of d-galactose, the yield of d-tagatose was 42% and no sugars other than d-tagatose and d-galactose were detected. Direct conversion of lactose to d-tagatose in a single reactor was demonstrated using a thermostable -galactosidase together with the thermostable l-arabinose isomerase. The two enzymes were also successfully combined with a commercially available glucose isomerase for conversion of lactose into a sweetening mixture comprising lactose, glucose, galactose, fructose and tagatose.     

Purification and properties of thermostable N-acylamino acid racemase from Amycolatopsis sp. TS-1-60

Thermostable N-acylamino acid recemase from Amycolatopsis sp. TS-1-60, a rare actinomycete strain selected for its ability to grow on agar plates incubated at 40° C, was purified to homogeneity and characterized. The relative molecular mass (M _r) of the native enzyme and the subunit was estimated to be 300 000 and 40 000 on gel filtration chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis respectively. The isoelectric point (pI) of the enzyme was 4.2. The optimum temperature and pH were 50° C and 7.5 respectively. The enzyme was stable at 55° C for 30 min. The enzyme catalyzed the racemization of optically active N-acylamino acids such as N-acetyl-l-or d-methionine, N-acetyl-l-valine, N-acetyl-l-tyrosine and N-chloroacetyl-l-valine. In addition, the enzyme also catalyzed the recemization of the dipeptide l-alanyl-l-methionine. By contrast, the optically active amino acids, N-alkyl-amino acids and methyl and athyl ester derivatives of N-acetyl-d- and l-methionine were not racemized. The apparent K _m values for N-acetyl-l-methionine and N-acetyl-d-methionine were calculated to be 18.5 mM and 11.3 mM respectively. The enzyme activity was markedly enhanced by the addition of divalent metal ions such as Co²⁺, Mn²⁺ and Fe²⁺ and was inhibited by addition of EDTA and P-chloromercuribenzoic acid. The similarity between the NH₂-terminal amino acid sequence of the enzyme and that of Streptomyces atratus Y-53 [Tokuyama et al. (1994) Appl Microbiol Biotechnol 40:835–840] was above 80%.     

Cloning,Purification and Characterization of an NAD-Dependent <Emphasis Type="SmallCaps">d</Emphasis>-Arabitol Dehydrogenase from Acetic Acid Bacterium, <Emphasis Type="Italic">Acetobacter suboxydans</Emphasis>

d-Xylulose-forming d-arabitol dehydrogenase (aArDH) is a key enzyme in the bio-conversion of d-arabitol to xylitol. In this study, we cloned the NAD-dependent d-xylulose-forming d-arabitol dehydrogenase gene from an acetic acid bacterium, Acetobacter suboxydans sp. The enzyme was purified from A. suboxydans sp. and was heterogeneously expressed in Escherichia coli. The native or recombinant enzyme was preferred NAD(H) to NADP(H) as coenzyme. The active recombinant aArDH expressed in E. coli is a homodimer, whereas the native aArDH in A. suboxydans is a homotetramer. On SDS–PAGE, the recombinant and native aArDH give one protein band at the position corresponding to 28 kDa. The optimum pH of polyol oxidation and ketone reduction is found to be pH 8.5 and 5.5 respectively. The highest reaction rate is observed when d-arabitol is used as the substrate (K _m = 4.5 mM) and the product is determined to be d-xylulose by HPLC analysis.