Reaction Kinetics of Substrate Transglycosylation Catalyzed by TreX of Sulfolobus solfataricus and Effects on Glycogen Breakdown

We studied the activity of a debranching enzyme (TreX) from Sulfolobus solfataricus on glycogen-mimic substrates, branched maltotetraosyl-β-cyclodextrin (Glc₄-β-CD), and natural glycogen to better understand substrate transglycosylation and the effect thereof on glycogen debranching in microorganisms. The validation test of Glc₄-β-CD as a glycogen mimic substrate showed that it followed the breakdown process of the well-known yeast and rat liver extract. TreX catalyzed both hydrolysis of α-1,6-glycosidic linkages and transglycosylation at relatively high (>0.5 mM) substrate concentrations. TreX transferred maltotetraosyl moieties from the donor substrate to acceptor molecules, resulting in the formation of two positional isomers of dimaltotetraosyl-α-1,6-β-cyclodextrin [(Glc₄)₂-β-CD]; these were 6¹,6³- and 6¹,6⁴-dimaltotetraosyl-α-1,6-β-CD. Use of a modified Michaelis-Menten equation to study substrate transglycosylation revealed that the k_cat and K_m values for transglycosylation were 1.78 × 10³ s⁻¹ and 3.30 mM, respectively, whereas the values for hydrolysis were 2.57 × 10³ s⁻¹ and 0.206 mM, respectively. Also, enzyme catalytic efficiency (the k_cat/K_m ratio) increased as the degree of polymerization of branch chains rose. In the model reaction system of Escherichia coli, glucose-1-phosphate production from glycogen by the glycogen phosphorylase was elevated ∼1.45-fold in the presence of TreX compared to that produced in the absence of TreX. The results suggest that outward shifting of glycogen branch chains via transglycosylation increases the number of exposed chains susceptible to phosphorylase action. We developed a model of the glycogen breakdown process featuring both hydrolysis and transglycosylation catalyzed by the debranching enzyme.     

Structural Enzymology of Cellvibrio japonicus Agd31B Protein Reveals α-Transglucosylase Activity in Glycoside Hydrolase Family 31

The metabolism of the storage polysaccharides glycogen and starch is of vital importance to organisms from all domains of life. In bacteria, utilization of these α-glucans requires the concerted action of a variety of enzymes, including glycoside hydrolases, glycoside phosphorylases, and transglycosylases. In particular, transglycosylases from glycoside hydrolase family 13 (GH13) and GH77 play well established roles in α-glucan side chain (de)branching, regulation of oligo- and polysaccharide chain length, and formation of cyclic dextrans. Here, we present the biochemical and tertiary structural characterization of a new type of bacterial 1,4-α-glucan 4-α-glucosyltransferase from GH31. Distinct from 1,4-α-glucan 6-α-glucosyltransferases (EC 2.4.1.24) and 4-α-glucanotransferases (EC 2.4.1.25), this enzyme strictly transferred one glucosyl residue from α(1→4)-glucans in disproportionation reactions. Substrate hydrolysis was undetectable for a series of malto-oligosaccharides except maltose for which transglycosylation nonetheless dominated across a range of substrate concentrations. Crystallographic analysis of the enzyme in free, acarbose-complexed, and trapped 5-fluoro-β-glucosyl-enzyme intermediate forms revealed extended substrate interactions across one negative and up to three positive subsites, thus providing structural rationalization for the unique, single monosaccharide transferase activity of the enzyme.     

Novel α-Glucosidase from Aspergillus nidulans with Strong Transglycosylation Activity

Aspergillus nidulans possessed an α-glucosidase with strong transglycosylation activity. The enzyme, designated α-glucosidase B (AgdB), was purified and characterized. AgdB was a heterodimeric protein comprising 74- and 55-kDa subunits and catalyzed hydrolysis of maltose along with formation of isomaltose and panose. Approximately 50% of maltose was converted to isomaltose, panose, and other minor transglycosylation products by AgdB, even at low maltose concentrations. The agdB gene was cloned and sequenced. The gene comprised 3,055 bp, interrupted by three short introns, and encoded a polypeptide of 955 amino acids. The deduced amino acid sequence contained the chemically determined N-terminal and internal amino acid sequences of the 74- and 55-kDa subunits. This implies that AgdB is synthesized as a single polypeptide precursor. AgdB showed low but overall sequence homology to α-glucosidases of glycosyl hydrolase family 31. However, AgdB was phylogenetically distinct from any other α-glucosidases. We propose here that AgdB is a novel α-glucosidase with unusually strong transglycosylation activity.     

Characterization of a novel amylolytic enzyme encoded by a gene from a soil-derived metagenomic library

It has been estimated that less than 1% of the microorganisms in nature can be cultivated by conventional techniques. Thus, the classical approach of isolating enzymes from pure cultures allows the analysis of only a subset of the total naturally occurring microbiota in environmental samples enriched in microorganisms. To isolate useful microbial enzymes from uncultured soil microorganisms, a metagenome was isolated from soil samples, and a metagenomic library was constructed by using the pUC19 vector. The library was screened for amylase activity, and one clone from among approximately 30,000 recombinant Escherichia coli clones showed amylase activity. Sequencing of the clone revealed a novel amylolytic enzyme expressed from a novel gene. The putative amylase gene (amyM) was overexpressed and purified for characterization. Optimal conditions for the enzyme activity of the AmyM protein were 42 degrees C and pH 9.0; Ca2+ stabilized the activity. The amylase hydrolyzed soluble starch and cyclodextrins to produce high levels of maltose and hydrolyzed pullulan to panose. The enzyme showed a high transglycosylation activity, making alpha-(1, 4) linkages exclusively. The hydrolysis and transglycosylation properties of AmyM suggest that it has novel characteristics and can be regarded as an intermediate type of maltogenic amylase, alpha-amylase, and 4-alpha-glucanotransferase.     

Occurrence of alpha-amylase in the axis of germinating peas

α-Amylase was found in the axis portion of ungerminated pea seeds (Pisum sativum var. Alaska). The occurrence of this enzyme was demonstrated with crude homogenates (also containing β-amylase) using three different methods: the hydrolysis of β-limit dextrin, the change in absorption spectra for the iodine-starch complex, and the increase in reducing materials relative to the decrease in starch. The first method was used to quantitate the changes in α-amylase activity during germination. The increase in total amylase activity (primarily β-amylase) paralleled germination; the accumulation of α-amylase activity was not initiated for an additional day. The increased α-amylase activity was related to epicotyl growth. Approximately half of this activity was found in the etiolated stem, the distribution being higher in growing than in nongrowing portions.     

Modes of action of acarbose hydrolysis and transglycosylation catalyzed by a thermostable maltogenic amylase, the gene for which was cloned from a Thermus strain

A maltogenic amylase gene was cloned in Escherichia coli from a gram-negative thermophilic bacterium, Thermus strain IM6501. The gene encoded an enzyme (ThMA) with a molecular mass of 68 kDa which was expressed by the expression vector p6xHis119. The optimal temperature of ThMA was 60 degrees C, which was higher than those of other maltogenic amylases reported so far. Thermal inactivation kinetic analysis of ThMA indicated that it was stabilized in the presence of 10 mM EDTA. ThMA harbored both hydrolysis and transglycosylation activities. It hydrolyzed beta-cyclodextrin and starch mainly to maltose and pullulan to panose. ThMA not only hydrolyzed acarbose, an amylase inhibitor, to glucose and pseudotrisaccharide (PTS) but also transferred PTS to 17 sugar acceptors, including glucose, fructose, maltose, cellobiose, etc. Structural analysis of acarbose transfer products by using methylation, thin-layer chromatography, high-performance ion chromatography, and nuclear magnetic resonance indicated that PTS was transferred primarily to the C-6 of the acceptors and at lower degrees to the C-3 and/or C-4. The transglycosylation of sugar to methyl-alpha-D-glucopyranoside by forming an alpha-(1,3)-glycosidic linkage was demonstrated for the first time by using acarbose and ThMA. Kinetic analysis of the acarbose transfer products showed that the C-4 transfer product formed most rapidly but readily hydrolyzed, while the C-6 transfer product was stable and accumulated in the reaction mixture as the main product.     

Crystal Structure of α-1,4-Glucan Lyase,a Unique Glycoside Hydrolase Family Member with a Novel Catalytic Mechanism

α-1,4-Glucan lyase (EC 4.2.2.13) from the red seaweed Gracilariopsis lemaneiformis cleaves α-1,4-glucosidic linkages in glycogen, starch, and malto-oligosaccharides, yielding the keto-monosaccharide 1,5-anhydro-d-fructose. The enzyme belongs to glycoside hydrolase family 31 (GH31) but degrades starch via an elimination reaction instead of hydrolysis. The crystal structure shows that the enzyme, like GH31 hydrolases, contains a (β/α)₈-barrel catalytic domain with B and B′ subdomains, an N-terminal domain N, and the C-terminal domains C and D. The N-terminal domain N of the lyase was found to bind a trisaccharide. Complexes of the enzyme with acarbose and 1-dexoynojirimycin and two different covalent glycosyl-enzyme intermediates obtained with fluorinated sugar analogues show that, like GH31 hydrolases, the aspartic acid residues Asp⁵⁵³ and Asp⁶⁶⁵ are the catalytic nucleophile and acid, respectively. However, as a unique feature, the catalytic nucleophile is in a position to act also as a base that abstracts a proton from the C2 carbon atom of the covalently bound subsite −1 glucosyl residue, thus explaining the unique lyase activity of the enzyme. One Glu to Val mutation in the active site of the homologous α-glucosidase from Sulfolobus solfataricus resulted in a shift from hydrolytic to lyase activity, demonstrating that a subtle amino acid difference can promote lyase activity in a GH31 hydrolase.     

Evolved β-Galactosidases from Geobacillus stearothermophilus with Improved Transgalactosylation Yield for Galacto-Oligosaccharide Production

A mutagenesis approach was applied to the β-galactosidase BgaB from Geobacillus stearothermophilus KVE39 in order to improve its enzymatic transglycosylation of lactose into oligosaccharides. A simple screening strategy, which was based on the reduction of the hydrolysis of a potential transglycosylation product (lactosucrose), provided mutant enzymes possessing improved synthetic properties for the autocondensation product from nitrophenyl-galactoside and galacto-oligosaccharides (GOS) from lactose. The effects of the mutations on enzyme activity and kinetics were determined. An change of one arginine to lysine (R109K) increased the oligosaccharide yield compared to that for the wild-type BgaB. Subsequently, saturation mutagenesis at this position demonstrated that valine and tryptophan further increased the transglycosylation performance of BgaB. During the transglycosylation reaction with lactose of the evolved β-galactosidases, a major trisaccharide was formed. Its structure was characterized as β-d-galactopyranosyl-(1→3)-β-d-galactopyranosyl-(1→4)-d-glucopyranoside (3′-galactosyl-lactose). At the lactose concentration of 18% (wt/vol), this trisaccharide was obtained in yields of 11.5% (wt/wt) with GP21 (BgaB R109K), 21% with GP637.2 (BgaB R109V), and only 2% with the wild-type BgaB enzyme. GP643.3 (BgaB R109W) was shown to be the most efficient mutant, with a 3′-galactosyl-lactose production of 23%.Galacto-oligosaccharides (GOS) are established prebiotic food ingredients and are used to enhance the growth of bifidobacteria and lactobacilli in the large intestine in order to reduce the growth of pathogenic microorganisms (3, 26, 27). The increased interest in these products by consumers heightened the need for good catalysts. Therefore, the development of an efficient and inexpensive GOS production method is highly desirable. One approach is to use lactose as a substrate for the preparation of prebiotic carbohydrates. Lactose is a low-value sugar comprising up to 75% of the total dry material in whey, and it accumulates in quantities of approximately 6 million tons annually worldwide (29). In several studies, GOS syntheses from lactose using different β-glycosidases had been reported (21). GOS are usually produced by the transglycosylation reaction during enzymatic hydrolysis of lactose. The proportion of transglycosylation to hydrolysis varies, depending on the different sources of enzymes (20, 22, 30, 31). In most cases yields of oligosaccharides are rather low; presumably the products are substrates for the enzyme and undergo hydrolysis.In order to overcome the hydrolysis problem, attempts to transform a glycosidase into a transglycosidase have been made. The generation of glycosynthases, which are mutants of glycosidases with a nonfunctional catalytically acting nucleophile amino acid residue, was one attempt to improve the transglycosylation yield. Many glycosynthases which demonstrated improved glycoside synthesis have been reported (8, 10, 12). However, this approach requires knowledge of the catalytically acting nucleophile residues of the glycosidase studied. Furthermore, activated glycosyl donors (e.g., glycosyl fluoride substrates of the opposite anomeric conformation) are needed for their enzymatic reaction. Therefore, their potential for use in industrial processes for large-scale production of GOS seems low, because of their inactivity on natural substrates (e.g., lactose).In a second approach, directed-evolution strategies have been used to enhance transglycosidase activity. Using random mutagenesis and in vitro recombination, Feng et al. (10) were able to diminish the hydrolytic activity of β-glycosidase from Thermus thermophilus while significantly increasing the transglycosylation activity. This allowed them to synthesize oligosaccharides through transglycosylation reactions with nitrophenyl-β-glycosides as donors and various glycosides as acceptors. The enhancement of the transglycosylation activities of β-glycosidases toward natural substrates such as lactose was achieved by active-site mutagenesis of β-glucosidase from Pyrococcus furiosus (13) or by using a truncated β-galactosidase from Bifidobacterium bifidum (19).The application of thermostable β-galactosidases is of interest in the conversion of lactose, because at higher temperatures higher lactose concentration can be used, favoring GOS synthesis. Thus, we explored the use of the thermophilic β-galactosidase BgaB from Geobacillus stearothermophilus for transglycosylation reaction on lactose to produce specific GOS. BgaB, belonging to glycoside hydrolase family 42 (15), cloned in Escherichia coli is able to hydrolyze lactose, but its GOS productivity is rather low. Thus, we aimed at increasing the synthetic yield of GOS from lactose exerted by the enzyme. Here we applied a random mutagenic approach together with a screening procedure to obtain mutants possessing higher transgalactosylation activity.     

Beta-Amylases from Alfalfa (Medicago sativa L.) Roots

Amylase was found in high activity (193 international units per milligram protein) in the tap root of alfalfa (Medicago sativa L. cv. Sonora). The activity was separated by gel filtration chromatography into two fractions with molecular weights of 65,700 (heavy amylase) and 41,700 (light amylase). Activity staining of electrophoretic gels indicated the presence of one isozyme in the heavy amylase fraction and two in the light amylase fraction. Three amylase isozymes with electrophoretic mobilities identical to those in the heavy and the light amylase fractions were the only amylases identified in crude root preparations. Both heavy and light amylases hydrolyzed amylopectin, soluble starch, and amylose but did not hydrolyze pullulan or β-limit dextrin. The ratio of viscosity change to reducing power production during starch hydrolysis was identical for both alfalfa amylase fractions and sweet potato β-amylase, while that of bacterial α-amylase was considerably higher. The identification of maltose and β-limit dextrin as hydrolytic end-products confirmed that these alfalfa root amylases are all β-amylases.     

Thermostable and alkalophilic maltogenic amylase of Bacillus thermoalkalophilus ET2 in monomer-dimer equilibrium

A gene encoding a thermostable and alkalophilic maltogenic amylase (BTMA) was cloned from the thermophilic bacterium Bacillus thermoalkalophilus ET2. BTMA was composed of 588 amino acids with a predicted molecular mass of 68.8 kDa. The enzyme had an optimal temperature and pH of 70°C and 8, respectively, the highest among maltogenic amylases reported so far. The Tm of BTMA at pH 8 was 76.7°C with an enthalpy of 113.6 kJ mol^-1. Both hydrolysis and transglycosylation activities for various carbohydrates were evident. β-Cyclodextrin (β-CD) and soluble starch were hydrolyzed mainly to maltose, and pullulan to panose. Acarbose, a strong amylase inhibitor, was hydrolyzed by BTMA to glucose and acarviosine-glucose. The K _m and k _cat values of BTMA for β-CD hydrolysis were 0.128 mM and 165.8 s^-1 mM, respectively. The overall catalytic efficiency (k _cat/K _m) of the enzyme was highest toward β-CD. BTMA was present in a monomer-dimer equilibrium with a molar ratio of 54:46 in 50 mM glycine-NaOH buffer (pH 8.0). This equilibrium could be affected by KCl and enzyme concentrations. The multi-substrate specificity of the enzyme was modulated by the structural differences between monomeric and dimeric forms. Starch was hydrolyzed more readily when monomeric BTMA was prevalent, while the opposite was observed for β-CD.     

Characterization of alpha-Amylase from Shoots and Cotyledons of Pea (Pisum sativum L.) Seedlings

The most abundant α-amylase (EC 3.2.1.1) in shoots and cotyledons from pea (Pisum sativum L.) seedlings was purified 6700-and 850-fold, respectively, utilizing affinity (amylose and cycloheptaamylose) and gel filtration chromatography and ultrafiltration. This α-amylase contributed at least 79 and 15% of the total amylolytic activity in seedling cotyledons and shoots, respectively. The enzyme was identified as an α-amylase by polarimetry, substrate specificity, and end product analyses. The purified α-amylases from shoots and cotyledons appear identical. Both are 43.5 kilodalton monomers with pls of 4.5, broad pH activity optima from 5.5 to 6.5, and nearly identical substrate specificities. They produce identical one-dimensional peptide fingerprints following partial proteolysis in the presence of SDS. Calcium is required for activity and thermal stability of this amylase. The enzyme cannot attack maltodextrins with degrees of polymerization below that of maltotetraose, and hydrolysis of intact starch granules was detected only after prolonged incubation. It best utilizes soluble starch as substrate. Glucose and maltose are the major end products of the enzyme with amylose as substrate. This α-amylase appears to be secreted, in that it is at least partially localized in the apoplast of shoots. The native enzyme exhibits a high degree of resistance to degradation by proteinase K, trypsin/chymostrypsin, thermolysin, and Staphylococcus aureus V8 protease. It does not appear to be a high-mannose-type glycoprotein. Common cell wall constituents (e.g. β-glucan) are not substrates of the enzyme. A very low amount of this α-amylase appears to be associated with chloroplasts; however, it is unclear whether this activity is contamination or α-amylase which is integrally associated with the chloroplast.     

Characterization of an endo-Acting Amylopullulanase from Thermoanaerobacter Strain B6A

A thermoanaerobe (Thermoanaerobacter sp.) grown in TYE-starch (0.5%) medium at 60°C produced both extra- and intracellular pullulanase (1.90 U/ml) and amylase (1.19 U/ml) activities. Both activities were produced at high levels on a variety of carbon sources. The temperature and pH optima for both pullulanase and amylase activities were 75°C and pH 5.0, respectively. Both the enzyme activities were stable up to 70°C (without substrate) and at pH 4.5 to 5.0. The half-lives of both enzyme activities were 5 h at 70°C and 45 min at 75°C. The enzyme activities did not show any metal ion activity, and both activities were inhibited by β- and γ-cyclodextrins but not by α-cyclodextrin. A single amylolytic pullulanase responsible for both activities was purified to homogeneity by DEAE-Sepharose CL-6B column chromatography, gel filtration using high-pressure liquid chromatography, and pullulan-Sepharose affinity chromatography. It was a 450,000-molecular-weight glycoprotein composed of two equivalent subunits. The pullulanase cleaved pullulan in α1,6 linkages and produced multiple saccharides from cleavage of α-1,4 linkages in starch. The K_ms for pullulan and soluble starch were 0.43 and 0.37 mg/ml, respectively.     

Purification,Cloning, Characterization,and N-Glycosylation Analysis of a Novel β-Fructosidase from Aspergillus oryzae FS4 Synthesizing Levan- and Neolevan-Type Fructooligosaccharides

β-Fructosidases are a widespread group of enzymes that catalyze the hydrolysis of terminal fructosyl units from various substrates. These enzymes also exhibit transglycosylation activity when they function with high concentrations of sucrose, which is used to synthesize fructooligosaccharides (FOS) in the food industry. A β-fructosidase (BfrA) with high transglycosylation activity was purified from Aspergillus oryzae FS4 as a monomeric glycoprotein. Compared with the most extensively studied Aspergillus spp. fructosidases that synthesize inulin-type β-(2-1)-linked FOS, BfrA has unique transfructosylating property of synthesizing levan- and neolevan-type β-(2-6)-linked FOS. The coding sequence (bfrAFS4, 1.86 kb) of BfrA was amplified and expressed in Escherichia coli and Pichia pastoris. Both native and recombinant proteins showed transfructosylation and hydrolyzation activities with broad substrate specificity. These proteins could hydrolyze the following linkages: Glc α-1, 2-β Fru; Glc α-1, 3-α Fru; and Glc α-1, 5-β Fru. Compared with the unglycosylated E. coli-expressed BfrA (E.BfrA), the N-glycosylated native (N.BfrA) and the P. pastoris-expressed BfrA (P.BfrA) were highly stable at a wide pH range (pH 4 to 11), and significantly more thermostable at temperatures up to 50°C with a maximum activity at 55°C. Using sucrose as substrate, the Km and k_cat values for total activity were 37.19±5.28 mM and 1.0016±0.039×10⁴ s⁻¹ for N.BfrA. Moreover, 10 of 13 putative N-glycosylation sites were glycosylated on N.BfrA, and N-glycosylation was essential for enzyme thermal stability and optima activity. Thus, BfrA has demonstrated as a well-characterized A. oryzae fructosidase with unique transfructosylating capability of synthesizing levan- and neolevan-type FOS.     

Bacillus stearothermophilus Neopullulanase Selective Hydrolysis of Amylose to Maltose in the Presence of Amylopectin

The specificity of Bacillus stearothermophilus TRS40 neopullulanase toward amylose and amylopectin was analyzed. Although this neopullulanase completely hydrolyzed amylose to produce maltose as the main product, it scarcely hydrolyzed amylopectin. The molecular mass of amylopectin was decreased by only one order of magnitude, from approximately 10⁸ to 10⁷ Da. Furthermore, this neopullulanase selectively hydrolyzed amylose when starch was used as a substrate. This phenomenon, efficient hydrolysis of amylose but not amylopectin, was also observed with cyclomaltodextrinase from alkaliphilic Bacillus sp. strain A2-5a and maltogenic amylase from Bacillus licheniformis ATCC 27811. These three enzymes hydrolyzed cyclomaltodextrins and amylose much faster than pullulan. Other amylolytic enzymes, such as bacterial saccharifying α-amylase, bacterial liquefying α-amylase, β-amylase, and neopullulanase from Bacillus megaterium, did not exhibit this distinct substrate specificity at all, i.e., the preference of amylose to amylopectin.     

Partial Purification and Characterization of a Thermostable Actinomycete β-Amylase

A thermostable amylase, possibly a β-amylase from Thermoactinomyces sp. no. 2 isolated from soil, is reported. The enzyme was purified 36-fold by acetone precipitation, ion-exchange chromatography, and Sephadex G-200 gel filtration, and the molecular weight was estimated at 31,600. The enzyme was characterized by demonstration of optimum activity at 60°C and pH 7 and by retention of 70% activity at 70°C (30 min). It was stimulated by Mn²⁺ and Fe²⁺ but strongly inhibited by Hg²⁺. Maltose was the only detectable product of hydrolysis of starches and was quantitatively highest in plantain starch hydrolysate.     

Characterization of Five β-Glycoside Hydrolases from Cellulomonas fimi ATCC 484

The Gram-positive bacterium Cellulomonas fimi produces a large array of carbohydrate-active enzymes. Analysis of the collection of carbohydrate-active enzymes from the recent genome sequence of C. fimi ATCC 484 shows a large number of uncharacterized genes for glycoside hydrolase (GH) enzymes potentially involved in biomass utilization. To investigate the enzymatic activity of potential β-glucosidases in C. fimi, genes encoding several GH3 enzymes and one GH1 enzyme were cloned and recombinant proteins were expressed in Escherichia coli. Biochemical analysis of these proteins revealed that the enzymes exhibited different substrate specificities for para-nitrophenol-linked substrates (pNP), disaccharides, and oligosaccharides. Celf_2726 encoded a bifunctional enzyme with β-d-xylopyranosidase and α-l-arabinofuranosidase activities, based on pNP-linked substrates (CfXyl3A). Celf_0140 encoded a β-d-glucosidase with activity on β-1,3- and β-1,6-linked glucosyl disaccharides as well as pNP-β-Glc (CfBgl3A). Celf_0468 encoded a β-d-glucosidase with hydrolysis of pNP-β-Glc and hydrolysis/transglycosylation activities only on β-1,6-linked glucosyl disaccharide (CfBgl3B). Celf_3372 encoded a GH3 family member with broad aryl-β-d-glycosidase substrate specificity. Celf_2783 encoded the GH1 family member (CfBgl1), which was found to hydrolyze pNP-β-Glc/Fuc/Gal, as well as cellotetraose and cellopentaose. CfBgl1 also had good activity on β-1,2- and β-1,3-linked disaccharides but had only very weak activity on β-1,4/6-linked glucose.     

Enzymatic synthesis of trisaccharides and alkyl β-d-glucosides by the transglycosylation reaction of β-glucosidase from Fusarium oxysporum

Purified β-glucosidase from Fusarium oxysporum catalyses hydrolysis and transglycosylation reactions. By utilizing the transglycosylation reaction, trisaccharides and alkyl β-d-glucosides were synthesized under optimal conditions in the presence of various disaccharides and alcohols. The yields of trisaccharides and alkyl β-d-glucosides were 22–37% and 10–33% of the total sugar, respectively. The enzyme retained 70–80% of its original activity in the presence of 25% (w/v) methanol, ethanol and propanol. Thus, β-glucosidase from F. oxysporum appears to be an ideal enzyme for the synthesis of useful trisaccharides and alkyl β-d-glucosides.     

Characterization of a Novel β-Glucosidase from a Compost Microbial Metagenome with Strong Transglycosylation Activity

The β-glucosidase encoded by the td2f2 gene was isolated from a compost microbial metagenomic library by functional screening. The protein was identified to be a member of the glycoside hydrolase family 1 and was overexpressed in Escherichia coli, purified, and biochemically characterized. The recombinant β-glucosidase, Td2F2, exhibited enzymatic activity with β-glycosidic substrates, with preferences for glucose, fucose, and galactose. Hydrolysis occurred at the nonreducing end and in an exo manner. The order of catalytic efficiency for glucodisaccharides and cellooligosaccharides was sophorose > cellotetraose > cellotriose > laminaribiose > cellobiose > cellopentaose > gentiobiose, respectively. Intriguingly, the p-nitrophenyl-β-d-glucopyranoside hydrolysis activity of Td2F2 was activated by various monosaccharides and sugar alcohols. At a d-glucose concentration of 1000 mm, enzyme activity was 6.7-fold higher than that observed in the absence of d-glucose. With 31.3 mm d-glucose, Td2F2 catalyzed transglycosylation to generate sophorose, laminaribiose, cellobiose, and gentiobiose. Transglycosylation products were detected under all activated conditions, suggesting that the activity enhancement induced by monosaccharides and sugar alcohols may be due to the transglycosylation activity of the enzyme. These results show that Td2F2 obtained from a compost microbial metagenome may be a potent candidate for industrial applications.     

Enhancement of the Alcoholytic Activity of α-Amylase AmyA from Thermotoga maritima MSB8 (DSM 3109) by Site-Directed Mutagenesis

AmyA, an α-amylase from the hyperthermophilic bacterium Thermotoga maritima, is able to hydrolyze internal α-1,4-glycosidic bonds in various α-glucans at 85°C as the optimal temperature. Like other glycoside hydrolases, AmyA also catalyzes transglycosylation reactions, particularly when oligosaccharides are used as substrates. It was found that when methanol or butanol was used as the nucleophile instead of water, AmyA was able to catalyze alcoholysis reactions. This capability has been evaluated in the past for some α-amylases, with the finding that only the saccharifying fungal amylases from Aspergillus niger and from Aspergillus oryzae present measurable alcoholysis activity (R. I. Santamaria, G. Del Rio, G. Saab, M. E. Rodriguez, X. Soberon, and A. Lopez, FEBS Lett. 452:346-350, 1999). In the present work, we found that AmyA generates larger quantities of alkyl glycosides than any amylase reported so far. In order to increase the alcoholytic activity observed in AmyA, several residues were identified and mutated based on previous analogous positions in amylases, defining the polarity and geometry of the active site. Replacement of residue His222 by glutamine generated an increase in the alkyl glucoside yield as a consequence of a higher alcoholysis/hydrolysis ratio. The same change in specificity was observed for the mutants H222E and H222D, but instability of these mutants toward alcohols decreased the yield of alkyl glucoside.     

Purification of a beta-Amylase that Accumulates in Arabidopsis thaliana Mutants Defective in Starch Metabolism

Amylase activity is elevated 5- to 10-fold in leaves of several different Arabidopsis thaliana mutants defective in starch metabolism when they are grown under a 12-hour photoperiod. Activity is also increased when plants are grown under higher light intensity. It was previously determined that the elevated activity was an extrachloroplastic β-(exo)amylase. Due to the location of this enzyme outside the chloroplast, its function is not known. The enzyme was purified to homogeneity from leaves of both a starchless mutant deficient in plastid phosphoglucomutase and from the wild type using polyethylene glycol fractionation and cyclohexaamylose affinity chromatography. The molecular mass of the β-amylase from both sources was 55,000 daltons as determined by denaturing gel electrophoresis. Gel filtration studies indicated that the enzyme was a monomer. The specific activities of the purified protein from mutant and wild-type sources, their substrate specificities, and K_m for amylopectin were identical. Based on these results it was concluded that the mutant contained an increased level of β-amylase protein. Enzyme neutralization studies using a polyclonal antiserum raised to purified β-amylase showed that in each of two starchless mutants, one starch deficient mutant and one starch overproducing mutant, the elevated amylase activity was due to elevated β-amylase protein.