Enzymatic Synthesis of α-Anomer-Selective D-Glucosides Using Maltose Phosphorylase

A maltose phosphorylase (EC 2.4.1.8; MPase) showed novel acceptor specificity and transferred the glucosyl moiety of maltose not only to sugars but also to various acceptors having alcoholic OH groups. Salicyl alcohol acted as acceptor for MPase from Enterococcus hirae, and the product, salicyl-O-α-D-glucopyranoside (α-SalGlc) was identified. The yield based on supplied salicyl alcohol was 86% (mol/mol).     

Engineering of Escherichia coli to facilitate efficient utilization of isomaltose and panose in industrial glucose feedstock

Industrial glucose feedstock prepared by enzymatic digestion of starch typically contains significant amounts of disaccharides such as maltose and isomaltose and trisaccharides such as maltotriose and panose. Maltose and maltosaccharides can be utilized in Escherichia coli fermentation using industrial glucose feedstock because there is an intrinsic assimilation pathway for these sugars. However, saccharides that contain α-1,6 bonds, such as isomaltose and panose, are still present after fermentation because there is no metabolic pathway for these sugars. To facilitate more efficient utilization of glucose feedstock, we introduced glvA, which encodes phospho-α-glucosidase, and glvC, which encodes a subunit of the phosphoenolpyruvate-dependent maltose phosphotransferase system (PTS) of Bacillus subtilis, into E. coli. The heterologous expression of glvA and glvC conferred upon the recombinant the ability to assimilate isomaltose and panose. The recombinant E. coli assimilated not only other disaccharides but also trisaccharides, including alcohol forms of these saccharides, such as isomaltitol. To the best of our knowledge, this is the first report to show the involvement of the microbial PTS in the assimilation of trisaccharides. Furthermore, we demonstrated that an l-lysine-producing E. coli harboring glvA and glvC converted isomaltose and panose to l-lysine efficiently. These findings are expected to be beneficial for industrial fermentation.

     

Studies on the Structure of Gluco-oligosaccharides Obtained from the Partial Acid Hydrolyzate of Sclerotia of Sclerotinia libertiana

The defatted sclerotia powder was partially hydrolyzed with dilute acid, and the material obtained was fractionated by carbon column chromatography, separated into two disaccharides, three trisaccharides and three tetrasaccharides, respectively. In these hydrolyzates α, α-trehalose, Iaminaribiose, and gentiobiose were identified.     

Biochemical Studies on Buckwheat α-Glucosidase

The transglucosylation action of buckwheat α-glucosidase on soluble starch, maltose maltotriose and maltotetraose are described and discussed. The transglucosylation products of soluble starch were isolated by carbon-Celite column chromatography and by paper chromatography. Among the products were found follows: nigerose, maltose, kojibiose and isomaltose as disaccharides and 2-α-isomaltosylglucose, 2-α-nigerosylglucose, nigerotriose. 3-α-maltosylglucose and maltotriose as trisaccharides.

Furthermore, the existence of 6-α-nigerosylglucose, 4-α-kojibiosylglucose, panose, isopanose and 3-α-isomaItosylglucose was suspected. A new trisaccharide, 2-α-nigerosylglucose which was obtained in a crystalline form (monohydrate) melted at 186~188°C and gave [α]_D+ 178.3 (c = 0.6, in water).

These experimental results on the reaction products seem to indicate that the activated glucosyl group from the substrate (starch, in this case) is transferred to any position of C–2,3,4 or 6 of glucose released from the substrate and the same type of transglucosylation occurrs upon the non-reducing terminal of disaccharides just produced, which leads to the formation of various kinds of trisaccharide, tetrasaccharide etc. The synthesis of α-oligosaccharides from free glucose could not be detected by paper chromatography.     

Enzymatic Synthesis of 2-Deoxyglycosides Using the ß-Glycosidase of the Archaeon Sulfolobus solfataricus

The synthesis of 2-deoxyglycosides and, for the first time, of 2-deoxygalactosides is reported using a thermophilic and thermostable β-glycosyl hydrolase from the archeon Sulfolobus solfataricus and glucal or galactal as donors. The yields observed with alkyl acceptors confirmed that the robustness of the biocatalyst is of great help in designing practical syntheses of pure β-anomers of 2-deoxy derivatives of 4-penten-1-ol (obtained in 80% yield at 20 fold molar excess) and 3,4-dimethoxybenzyl alcohol (obtained in 19% yield at 3.3 fold molar excess). The attachment of 2-deoxyglyco units was performed on various pyranosidic acceptors (p-nitrophenyl α-d-glucopyranoside, o-nitrophenyl 2-deoxy-N-acetyl-α-d-glucosamine and p-nitrophenyl 2-deoxy-N-acetyl-β-d-glucosamine). At low molecular excesses of the acceptors, satisfactory yields (20-40%) of chromophoric 2-deoxy di- and trisaccharides were obtained. The different regioselectivity of our enzyme with respect to mesophilic counterparts reflects the importance of biodiversity in this field for the construction of a library of different glycosidases with different specificity.     

Trehalose Lipid and α-Branched-β-hydroxy Fatty Acid Formed by Bacteria Grown on n-Alkanes

A bacterium isolated in our laboratory, Arthrobacter paraffineus KY 4303. when grown on n-paraffin as the sole source of carbon, produced anthrone-positive lipid in the emulsion layer (holding bacterial cells, lipids and n-paraffin remained) of the culture medium. This was isolated and identified as α-branched-β-hydroxy fatty acid trehalose ester.

The addition of penicillin to the growing culture caused a significant suppression of trehalose lipid formation and led consequently to the accumulation of both the precursors, α, α-trehalose and α-branched-β-hydroxy fatty acid, in the culture medium.

The formation of trehalose lipid was also observed in other bacteria which can utilize n-paraffin as the sole source of carbon. In addition, a possible role of this trehalose lipid in the utilization of n-paraffin by these bacteria was discussed.     

Production of keto-disaccharides from aldo-disaccharides in subcritical aqueous ethanol

Isomerization of disaccharides (maltose, isomaltose, cellobiose, lactose, melibiose, palatinose, sucrose, and trehalose) was investigated in subcritical aqueous ethanol. A marked increase in the isomerization of aldo-disaccharides to keto-disaccharides was noted and their hydrolytic reactions were suppressed with increasing ethanol concentration. Under any study condition, the maximum yield of keto-disaccharides produced from aldo-disaccharides linked by β-glycosidic bond was higher than that produced from aldo-disaccharides linked by α-glycosidic bond. Palatinose, a keto-disaccharide, mainly underwent decomposition rather than isomerization in subcritical water and subcritical aqueous ethanol. No isomerization was noted for the non-reducing disaccharides trehalose and sucrose. The rate constant of maltose to maltulose isomerization almost doubled by changing solvent from subcritical water to 80 wt% aqueous ethanol at 220 °C. Increased maltose monohydrate concentration in feed decreased the conversion of maltose and the maximum yield of maltulose, but increased the productivity of maltulose. The maximum productivity of maltulose was ca. 41 g/(h kg-solution).     

Comparative Biochemical Studies of α-Glucosidases

The properties of brewer’s yeast α-glucosidase have been investigated. The enzyme was capable of hydrolyzing various α-glucosides and was active especially on aryl-α-glucosides in comparison with other α-glucosides and sugars. The rate of hydrolysis decreased in following order: phenyl-α-glucosides, sucrose, matlose and isomaltose.

The range of opt. temp, was 40~45°C and opt. pH, 6.5~7.0.

Cu⁺⁺ and Hg⁺⁺ inhibited strongly the enzyme activity and Zn⁺⁺, moderately. The enzyme was suggested to be a sulfhydryl enzyme from the inhibition experiments by SH-reagents and the effects of glutathione on the activity.

The enzyme synthesized some oligosaccharides from maltose. As the transglucosidation products, nigerose, isomaltose, kojibiose and maltotriose were detected by paperchromatography.

Pure nigerose was separated by splitting maltose with amyloglucosidase from the mixture of maltose and nigerose and by use of successive carbon column chromatography.     

Synthesis of Maltosyl(α1→6)cyclodextrins through the Reverse Reaction of Thermostable Bacillus acidopullulyticus Pullulanase

Maltosyl(α1→6)α-, β or γ-cyclodextrin was synthesized from maltose and α-, β- or γ- cyclodextrin, respectively, using Bacillus acidopullulyticus pullulanase (EC 3.2.1.41). More than 40% of each cyclodextrin substrate was converted to the corresponding maltosyl(α1→6)cyclodextrin under the conditions given below; the combined concentration of maltose and cyclodextrin was 70 ~ 75 % (w/w), the molar ratio of maltose to cyclodextrin was 9~18, and the amount of pullulanase was 100~200units/g of cyclodextrin. The optimum pH and temperature for the formation of maltosyl(α1→6)cyclodextrins were 4.0—4.5 and 60~70°C, respectively. Each maltosyl(α1→6)-cyclodextrin produced was separated from noncyclic saccharides, maltose and branched tetraose, by methanol and ethanol precipitations. The maltosyl(α1→6)cyclodextrins were further purified by gel filtration on a Toyopearl HW 40 S column and crystallization from aqueous (for maltosyl(α1→6)β-cyclodextrin) or methanol (for maltosyl(α1→6)β-cyclodextrin) solution. From 10 g each of the corresponding cyclodextrin, the yields of the purified maltosyl(α1→6)α-, β- and γ-cylcodextrins were 3.0 ~ 3.6 g, 2.5 ~ 2.8g and 2.2 ~ 2.5 g, respectively. Identification of the maltosyl(α1-6)cyclo-dextrins was performed by means of hydrolysis with Klebsiella pneumoniae pullulanase, methyla- tion analysis and ¹³C-NMR analysis.     

Ant-aphid mutualisms: the impact of honeydew production and honeydew sugar composition on ant preferences

The honeydew composition and production of four aphid species feeding on Tanacetum vulgare, and mutualistic relationships with the ant Lasius niger were studied. In honeydew of Metopeurum fuscoviride and Brachycaudus cardui, xylose, glucose, fructose, sucrose, maltose, melezitose, and raffinose were detected. The proportion of trisaccharides (melezitose, raffinose) ranged between 20% and 35%. No trisaccharides were found in honeydew of Aphis fabae, and honeydew of Macrosiphoniella tanacetaria consisted of only xylose, glucose and sucrose. M. fuscoviride produced by far the largest amounts of honeydew per time unit (880 μg/aphid per hour), followed by B. cardui (223 μg/aphid per hour), A. fabae (133 μg/aphid per hour) and M. tanacetaria (46 μg/aphid per hour). The qualitative and quantitative honeydew production of the aphid species corresponded well with the observed attendance by L. niger. L. niger workers preferred trisaccharides over disaccharides and monosaccharides when these sugars were offered in choice tests. The results are consistent with the ants' preference for M. fuscoviride, which produced the largest amount of honeydew including a considerable proportion of the trisaccharides melezitose and raffinose. The preference of L. niger for B. cardui over A. fabae, both producing similar amounts of honeydew, may be explained by the presence of trisaccharides and the higher total sugar concentration in B. cardui honeydew. M. tanacetaria, which produced only low quantities of honeydew with no trisaccharides was not attended at all by L. niger. Received: 2 March 1998 / Accepted: 16 November 1998     

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.     

Synthesis of three oligosaccharides that form part of the complex type of carbohydrate moiety of glycoproteins

Silver trifluoromethanesulfonate-promoted condensation of 3,4,6-tri-O-acetyl-2-deoxy-phthalimido-β-d-glucopyranosyl bromide with benzyl 3,6-di-O-benzyl-α-d-mannopyranoside and benzyl 3,4-di-O-benzyl-α-d-mannopyranoside gave the protected 2,4- and 2,6-linked trisaccharides in yields of 54 and 32%, respectively. After exchanging the 2-deoxy-2-phthalimido groups for 2-acetamido-2-deoxy groups and de-blocking, the trisaccharides 2,4-di-O-(2-acetamido-2-deoxy-β-d-glucopyranosyl)-d-mannose and 2,6-di-O-(2-acetamido-2-deoxy-β-d-glucopyranosyl)-d-mannose were obtained. Similar condensation of 3,6-di-O-acetyl-2-deoxy-2-phthalimido-4-O-(2,3,4,6-tetra-O-acetyl-β-d-galactopyranosyl)-β-d-glucopyranosyl bromide with benzyl 3,4-di-O-benzyl-α-d-mannopyranoside gave a pentasaccharide derivative in 52% yield. After transformations analogous to those applied to the trisaccharides, 2,6-di-O-[β-d-galactopyranosyl-(1→4)-O-(2-acetamido-2-deoxy-β-d-glucopyranosyl)]-d-mannose was obtained.     

Amino Acid Sequence of an Active Center Peptide Containing Serine Isolated from Alkaline Protease of Bacillus No. 221

The substrate specificity of pig liver acid α-glucosidase was investigated. The enzyme showed a wide specificity on various substrates. The Km values for maltose, malto-triose, -tetraose, -pentaose, -hexaose and -heptaose, and maltodextrin (mean degree of polymerization, 13) were 6.7 mm, 4.4 mm, 5.9 mm, ll mm, 4.0 mm, 5.6 mm and 7.1 mm, respectively. The relative maximum velocities for maltooligosaccharides consisting of three or more glucose units were 82.6 to 92.3% of the maximum velocity for maltose. For disaccharides, the rates of hydrolysis decreased in the following order: maltose > nigerose > kojibiose > isomaltose. The acid α-glucosidase also hydrolyzed several α-glucans, such as glycogen, soluble starch, β-limit dextrin and amylopectin. The Km value for β-limit dextrin was the lowest of those for α-glucans.

The nature of the active site catalyzing the hydrolyses of maltose and glycogen was investigated by kinetic methods. In experiments with mixed substrates, maltose and glycogen, the kinetic features agreed very closely with those theoretically predicted for a single active site catalyzing the hydrolyses of both substrates. Cations, Na⁺, K⁺ and Mg⁺⁺, were about equally effective in the activation of the enzyme action on maltose and glycogen. The inhibitor constants of tris(hydroxymethyl)aminomethane (Tris) and turanose were nearly the same for maltase activity as those for glucoamylase activity. From these results, the enzyme was concluded to attack maltose and glycogen by a single active site mechanism.     

Heterooligosaccharide synthesis catalyzed by α-glucosidase from Bacillus stearothermophilus

α-Glucosidase from Bacillus stearothermophilus was used as a catalyst for oligosaccharide synthesis by reversed hydrolysis. The yield of disaccharides and trisaccharides depended strongly on the units of enzyme activity added, and on the stability of the enzyme under reaction conditions. When glucose was the only saccharide present in the reaction mixture with α-glucosidase, isomaltose (51%), nigerose (25%), maltose (14%) and kojibiose (10%) were formed. In 50% glucose solution, disaccharide concentrations reached up to 400 mmol/l and trisaccharides were also produced. When other saccharides (mannose or xylose), in addition to glucose, were present in the reaction mixture, both homodisaccharides and heterodisaccharides were formed, their quantity being dependent on the glucose/saccharide acceptor ratios. The highest yields of oligosaccharides were observed with glucose alone, consistent with the observation that the enzyme stability was highest with glucose as the sole saccharide.     

Enzymatic synthesis of alpha-anomer-selective D-glucosides using maltose phosphorylase

A maltose phosphorylase (EC 2.4.1.8; MPase) showed novel acceptor specificity and transferred the glucosyl moiety of maltose not only to sugars but also to various acceptors having alcoholic OH groups. Salicyl alcohol acted as acceptor for MPase from Enterococcus hirae, and the product, salicyl-O-alpha-D-glucopyranoside (alpha-SalGlc) was identified. The yield based on supplied salicyl alcohol was 86% (mol/mol).     

Characterization of a glucansucrase from Lactobacillus reuteri E81 and production of malto-oligosaccharides

Abstract

Glucansucrases, which can be produced by different Lactic Acid Bacteria (LAB), catalyze the synthesis of α-glucans with different structures and properties using sucrose as substrate. In this study, a novel glucansucrase (GTFA) from Lactobacillus reuteri E81 was identified and heterologously expressed. Alignments of GTFA with other glucansucrases revealed its novelty and a putative 3D model structure was obtained. The biochemical properties of the truncated enzyme without the N-terminal variable region, GTFA-ΔN, was characterized. The K_m and V_max were found to be 7.5?mM and 1.49?IU/mg, respectively, and it showed optimum activities at pH 7 and at 50?°C. The GTFA-ΔN produced in vitro an α-glucan with (α1 → 3) and (α1 → 6) glycosidic linkages using sucrose as the substrate. Importantly, GTFA-ΔN synthesized DP = 9 oligosaccharides using sucrose and maltose as the donor and acceptor sugars, respectively, as detected by TLC, HPLC, LC-MS and NMR analysis.     

Trehalose synthesis from maltose by a thermostable trehalose synthase from Thermus caldophilus

Purified trehalose synthase from Thermus caldophilus GK24 produced 18–86% trehalose from 10 mM–1 M maltose. The enzyme also catalyzed the conversion of ,-trehalose into maltose but did not act on other disaccharides. The yield of trehalose from maltose by this enzyme increased 30% more at 40°C than at 80°C and was independent of the substrate concentration. The maximum yield of ,-trehalose from 10 mM maltose reached 86% at 40°C. In addition, ,-trehalose was also formed from maltose or ,-trehalose at 3.5% yield at 80°C. © Rapid Science Ltd. 1998     

Enzymatic synthesis of β-xylosyl-oligosaccharides by transxylosylation using two β-xylosidases of glycoside hydrolase family 3 from Aspergillus nidulans FGSC A4

Two β-xylosidases of glycoside hydrolase family 3 (GH 3) from Aspergillus nidulans FGSC A4, BxlA and BxlB were produced recombinantly in Pichia pastoris and secreted to the culture supernatants in yields of 16 and 118 mg/L, respectively. BxlA showed about sixfold higher catalytic efficiency (k_cat/K_m) than BxlB towards para-nitrophenyl β-d-xylopyranoside (pNPX) and β-1,4-xylo-oligosaccharides (degree of polymerisation 2–6). For both enzymes k_cat/K_m decreased with increasing β-1,4-xylo-oligosaccharide chain length. Using pNPX as donor with 9 monosaccharides, 7 disaccharides and two sugar alcohols as acceptors 18 different β-xylosyl-oligosaccharides were synthesised in 2–36% (BxlA) and 6–66% (BxlB) yields by transxylosylation. BxlA utilised the monosaccharides d-mannose, d-lyxose, d-talose, d-xylose, d-arabinose, l-fucose, d-glucose, d-galactose and d-fructose as acceptors, whereas BxlB used the same except for d-lyxose, d-arabinose and l-fucose. BxlB transxylosylated the disaccharides xylobiose, lactulose, sucrose, lactose and turanose in upto 35% yield, while BxlA gave inferior yields on these acceptors. The regioselectivity was acceptor dependent and primarily involved β-1,4 or 1,6 product linkage formation although minor products with different linkages were also obtained. Five of the 18 transxylosylation products obtained from d-lyxose, d-galactose, turanose and sucrose (two products) as acceptors were novel xylosyl-oligosaccharides, β-d-Xylp-(1→4)-d-Lyxp, β-d-Xylp-(1→6)-d-Galp, β-d-Xylp-(1→4)-α-d-Glcp-(1→3)-β-d-Fruf, β-d-Xylp-(1→4)-α-d-Glcp-(1→2)-β-d-Fruf, and β-d-Xylp-(1→6)-β-d-Fruf-(2→1)-α-d-Glcp, as structure-determined by 2D NMR, indicating that GH3 β-xylosidases are able to transxylosylate a larger variety of carbohydrate acceptors than earlier reported. Furthermore, transxylosylation of certain acceptors resulted in mixtures. Some of these products are also novel, but the structures of the individual products could not be determined.     

Structural Determination of Monosialyl Trisaccharides Obtained From Caprine Colostrum

Acidic oligosaccharides were separated by dialysis, ion-exchange, preparative paper and gel chromatography from caprine colostrum. Four sialyl trisaccharides were characterized by ¹H-NMR spectrometry as follows: α-N-acetylneuraminyl-(2,6)-β-d-galactopyranosyl-(1,4)-2-N-acetamido-2-deoxy-d-glucopyranose (Neu5Ac α 2-6Gal β 1-4GlcNAc), α-N-acetylneuraminyl-(2,3)-β-d-galactopyranosyl-(1,4)-d-glucopyranose (Neu5Ac α 2-3Gal β-1-4Glc), α-N-acetylneuraminyl-(2,6)-β-d-galactopyranosyl-(1,4)-d-glucopyranose (Neu5Ac α 2-6Gal β 1-4Glc) and α-N-glycolylneuraminyl-(2,6)-β-d-galactopyranosyl-(1,4)-d-glucopyranose (Neu5Gc α 2-6Gal β 1-4Glc).     

Microbial production of neryl-α-D-glucopyranoside from nerol by Agrobacterium sp. M-12 reflects glucosyl transfer activity

ABSTRACT

Terpene alcohol is widely used in perfumes and is known to possess antibacterial activity. Moreover, in its glycosylated form, it can be applied as a nonionic surfactant in food, and in the pharmaceutical, chemical, cosmetic, and detergent industries. Presently, chemical production of terpene glucosides is hampered by high costs and low yields. Here, we investigated the microbial glucosylation of nerol (cis-3,7-dimethylocta-2,6-dien-1-ol), a component of volatile oils, by Agrobacterium sp. M-12 isolated from soil. A microbial reaction using washed cells of Agrobacterium sp. M-12, 1 g/L of nerol, and 100 g/L of maltose under optimal conditions yielded 1.8 g/L of neryl-α-D-glucopyranoside after 72 h. The molar yield of neryl-α-D-glucopyranoside was 87.6%. Additionally, we report the successful transglucosylation of other monoterpene alcohols, such as geraniol, (-)-β-citronellol, and (-)-linalool, by Agrobacterium sp. M-12. Thus, microbial glucosylation has potential widespread applicability for efficient, low-cost production of glycosylated terpene alcohols.