Your search keyword '"Glucosyltransferases chemistry"' showing total 62 results

1. High-yield production of completely linear dextrans and isomalto-oligosaccharides by a truncated dextransucrase from Ligilactobacillus animalis TMW 1.971.

Author

Müller O and Wefers D

Subjects

Sucrose metabolism, Sucrose chemistry, Leuconostocaceae metabolism, Leuconostocaceae enzymology, Leuconostocaceae chemistry, Dextrans chemistry, Dextrans biosynthesis, Glucosyltransferases metabolism, Glucosyltransferases chemistry, Oligosaccharides chemistry, Oligosaccharides biosynthesis, Oligosaccharides metabolism

Abstract

Several lactic acid bacteria are capable of producing water-soluble exopolysaccharides such as dextran from sucrose by using glucansucrases. Several recombinant glucansucrases were described, however, yields were often limited and most dextrans were branched at position O3. In this study, the dextransucrase from Ligilactobacillus animalis TMW 1.971 was recombinantly produced without its N-terminal variable region and used for dextran synthesis. The enzyme expressed well and showed very high total as well as transferase activities compared to other glucansucrases. It was able to transfer nearly all glucose from sucrose to oligo- and polymeric products under certain conditions (about 95 % of glucose transferred). The high efficiency of the enzyme made it possible to obtain absolute dextran yields of up to 214.9 g/L from a 1.5 M sucrose solution. Structural characterization of the products showed that the dextrans produced have a rather low molecular weight, a narrow size distribution, and are completely linear. Furthermore, we showed that various low molecular weight dextrans or 1,6-linked isomalto-oligosaccharides can be efficiently produced by acid hydrolysis. Overall, we demonstrated that Ligilactobacillus animalis TMW 1.971 dextransucrase can be used to efficiently synthesize dextrans with a quite unique structural composition. The dextrans produced have a high potential for further applications such as synthesis of copolymers or size standards with a very defined molecular structure., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2024

2. Design Optimization of a Novel Catalytic Approach for Transglucosylated Isomaltooligosaccharides into Dietary Polyols Structures by Leuconostoc mesenteroides Dextransucrase.

Author

Muñoz-Labrador A, Doyagüez EG, Azcarate S, Julio-Gonzalez C, Barile D, Moreno FJ, and Hernandez-Hernandez O

Subjects

Bacterial Proteins chemistry, Bacterial Proteins metabolism, Polymers chemistry, Polymers metabolism, Biocatalysis, Sweetening Agents chemistry, Sweetening Agents metabolism, Glycosylation, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Oligosaccharides chemistry, Oligosaccharides metabolism, Leuconostoc mesenteroides enzymology, Leuconostoc mesenteroides chemistry, Leuconostoc mesenteroides metabolism

Abstract

Polyols, or sugar alcohols, are widely used in the industry as sweeteners and food formulation ingredients, aiming to combat the incidence of diet-related Non-Communicable Diseases. Given the attractive use of Generally Regarded As Safe (GRAS) enzymes in both academia and industry, this study reports on an optimized process to achieve polyols transglucosylation using a dextransucrase enzyme derived from Leuconostoc mesenteroides . These enzyme modifications could lead to the creation of a new generation of glucosylated polyols with isomalto-oligosaccharides (IMOS) structures, potentially offering added functionalities such as prebiotic effects. These reactions were guided by a design of experiment framework, aimed at maximizing the yields of potential new sweeteners. Under the optimized conditions, dextransucrase first cleared the glycosidic bond of sucrose, releasing fructose with the formation of an enzyme-glucosyl covalent intermediate complex. Then, the acceptor substrate (i.e., polyols) is bound to the enzyme-glucosyl intermediate, resulting in the transfer of glucosyl unit to the tested polyols. Structural insights into the reaction products were obtained through nuclear maneic resonance (NMR) and matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) analyses, which revealed the presence of linear α(1 → 6) glycosidic linkages attached to the polyols, yielding oligosaccharide structures containing from 4 to 10 glucose residues. These new polyols-based oligosaccharides hold promise as innovative prebiotic sweeteners, potentially offering valuable health benefits.

Published

2024

3. Improvement of combined cross-linked enzyme aggregates of cyclodextrin glucanotransferase and maltogenic amylase by functionalization of cross-linker for maltooligosaccharides synthesis.

Author

Yip YS, Jaafar NR, Rahman RA, Puspaningsih NNT, Jailani N, and Illias RM

Subjects

Cross-Linking Reagents chemistry, Bacillus enzymology, Protein Aggregates, Molecular Docking Simulation, Enzyme Stability, Glycoside Hydrolases, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Oligosaccharides chemistry, Oligosaccharides chemical synthesis, Chitosan chemistry, Chitosan analogs & derivatives

Abstract

Combined cross-linked enzyme aggregates of cyclodextrin glucanotransferase (CGTase) and maltogenic amylase (Mag1) from Bacillus lehensis G1 (Combi-CLEAs-CM) were successfully developed to synthesis maltooligosaccharides (MOS). Yet, the poor cross-linking performance between chitosan (cross-linker) and enzymes resulting low activity recovery and catalytic efficiency. In this study, we proposed the functionalization of cross-linkers with the integration of computational analysis to study the influences of different functional group on cross-linkers in combi-CLEAs development. From in-silico analysis, O-carboxymethyl chitosan (OCMCS) with the highest binding affinity toward both enzymes was chosen and showed alignment with the experimental result, in which OCMCS was synthesized as cross-linker to develop improved activity recovery of Combi-CLEAs-CM-ocmcs (74 %). The thermal stability and deactivation energy (205.86 kJ/mol) of Combi-CLEAs-CM-ocmcs were found to be higher than Combi-CLEAs-CM (192.59 kJ/mol). The introduction of longer side chain of carboxymethyl group led to a more flexible structure of Combi-CLEAs-CM-ocmcs. This alteration significantly reduced the K m value of Combi-CLEAs-CM-ocmcs by about 3.64-fold and resulted in a greater K cat /K m (3.63-fold higher) as compared to Combi-CLEAs-CM. Moreover, Combi-CLEAs-CM-ocmcs improved the reusability with retained >50 % of activity while Combi-CLEAs-CM only 36.18 % after five cycles. Finally, maximum MOS production (777.46 mg/g) was obtained by Combi-CLEAs-CM-ocmcs after optimization using response surface methodology., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Rosli bin Md Illias reports financial support was provided by Universiti Teknologi Malaysia. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024

4. Large scale production of lacto- N -biose I, a building block of type I human milk oligosaccharides, using sugar phosphorylases.

Author

Nishimoto M

Subjects

Acetylglucosamine chemical synthesis, Acetylglucosamine chemistry, Acetylglucosamine metabolism, Anion Exchange Resins chemistry, Bifidobacterium growth & development, Crystallization, Disaccharidases metabolism, Gastrointestinal Microbiome physiology, Hot Temperature, Humans, Hydrogen-Ion Concentration, Infant, Newborn, Acetylglucosamine analogs & derivatives, Bifidobacterium metabolism, Glucosyltransferases chemistry, Milk, Human chemistry, Oligosaccharides metabolism, Sucrose chemistry

Abstract

Human milk oligosaccharides (HMOs) have drawn attention for their contribution to the explosive bifidobacterial growth in the intestines of neonates. We found that bifidobacteria can efficiently metabolize lacto- N -biose I (LNB), the major building blocks of HMOs, and we have developed a method to synthesize LNB by applying this system. We produced LNB on a kilogram scale by the method. This proved that, among the enterobacteria, only bifidobacteria can assimilate LNB, and provided the data that supported the explosive growth of bifidobacteria in neonates. Furthermore, we were also able to reveal the structure of LNB crystal and the low stability for heating at neutral pH, which has not been clarified so far. In this paper, using bifidobacteria and LNB as examples, I describe the research on oligosaccharide synthesis that was conducted by utilizing a sugar metabolism. Abbreviations : LNB: lacto- N -biose I; GNB: galacto- N -biose; HMOs: human milk oligosaccharides; GLNBP: GNB/LNB phosphorylase; NahK: N -acetylhexosamine 1-kinase; GalT: UDP-glucose-hexose-1-phosphate uridylyltransferase; GalE: UDP-glucose 4-epimerase; SP: sucrose phosphorylase.

Published

2020

5. Carboxy-Terminal Region of a Thermostable CITase from Thermoanaerobacter thermocopriae Has the Ability to Produce Long Isomaltooligosaccharides.

Author

Jeong WS, Lee YR, Hong SJ, Choi SJ, Choi JH, Park SY, Woo EJ, Kim YM, and Park BR

Subjects

Catalytic Domain, Cloning, Molecular, Enzyme Stability, Escherichia coli genetics, Glucosyltransferases genetics, Glycoside Hydrolases, Hydrogen-Ion Concentration, Molecular Weight, Polymerization, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Sequence Analysis, Protein, Temperature, Thermoanaerobacter genetics, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Oligosaccharides metabolism, Thermoanaerobacter enzymology

Abstract

Isomaltooligosaccharides (IMOs) have good prebiotic effects, and long IMOs (LIMOs) with a degree of polymerization (DP) of 7 or above show improved effects. However, they are not yet commercially available, and require costly enzymes and processes for production. The Nterminal region of the thermostable Thermoanaerobacter thermocopriae cycloisomaltooligosaccharide glucanotransferase (TtCITase) shows cyclic isomaltooligosaccharide (CI)-producing activity owing to a catalytic domain of glycoside hydrolase (GH) family 66 and carbohydrate-binding module (CBM) 35. In the present study, we elucidated the activity of the C-terminal region of TtCITase (TtCITase-C; Met740-Phe1,559), including a CBM35-like region and the GH family 15 domain. The domain was successfully cloned, expressed, and purified as a single protein with a molecular mass of 115 kDa. TtCITase-C exhibited optimal activity at 40°C and pH 5.5, and retained 100% activity at pH 5.5 after 18-h incubation. TtCITase-C synthesized α-1,6 glucosyl products with over seven degrees of polymerization (DP) by an α-1,6 glucosyl transfer reaction from maltopentaose, isomaltopentaose, or commercialized maltodextrins as substrates. These results indicate that TtCITase-C could be used for the production of α-1,6 glucosyl oligosaccharides with over DP7 (LIMOs) in a more cost-effective manner, without requiring cyclodextran.

Published

2019

6. The structure of a GH149 β-(1 → 3) glucan phosphorylase reveals a new surface oligosaccharide binding site and additional domains that are absent in the disaccharide-specific GH94 glucose-β-(1 → 3)-glucose (laminaribiose) phosphorylase.

Author

Kuhaudomlarp S, Stevenson CEM, Lawson DM, and Field RA

Subjects

Bacterial Proteins metabolism, Binding Sites, Catalytic Domain, Crystallography, X-Ray, Glucosyltransferases metabolism, Glycosides chemistry, Models, Molecular, Oligosaccharides chemistry, Phosphorylases metabolism, Protein Conformation, Protein Domains, Substrate Specificity, beta-Glucans chemistry, Bacterial Proteins chemistry, Glucosyltransferases chemistry, Glycosides metabolism, Oligosaccharides metabolism, Phosphorylases chemistry, beta-Glucans metabolism

Abstract

Glycoside phosphorylases (GPs) with specificity for β-(1 → 3)-gluco-oligosaccharides are potential candidate biocatalysts for oligosaccharide synthesis. GPs with this linkage specificity are found in two families thus far-glycoside hydrolase family 94 (GH94) and the recently discovered glycoside hydrolase family 149 (GH149). Previously, we reported a crystallographic study of a GH94 laminaribiose phosphorylase with specificity for disaccharides, providing insight into the enzyme's ability to recognize its' sugar substrate/product. In contrast to GH94, characterized GH149 enzymes were shown to have more flexible chain length specificity, with preference for substrate/product with higher degree of polymerization. In order to advance understanding of the specificity of GH149 enzymes, we herein solved X-ray crystallographic structures of GH149 enzyme Pro_7066 in the absence of substrate and in complex with laminarihexaose (G6). The overall domain organization of Pro_7066 is very similar to that of GH94 family enzymes. However, two additional domains flanking its catalytic domain were found only in the GH149 enzyme. Unexpectedly, the G6 complex structure revealed an oligosaccharide surface binding site remote from the catalytic site, which, we suggest, may be associated with substrate targeting. As such, this study reports the first structure of a GH149 phosphorylase enzyme acting on β-(1 → 3)-gluco-oligosaccharides and identifies structural elements that may be involved in defining the specificity of the GH149 enzymes., (© 2019 The Authors. Proteins: Structure, Function, and Bioinformatics published by Wiley Periodicals, Inc.)

Published

2019

7. Alginate-pectin co-encapsulation of dextransucrase and dextranase for oligosaccharide production from sucrose feedstocks.

Author

Sharma M, Sangwan RS, Khatkar BS, and Singh SP

Subjects

Bacterial Proteins genetics, Dextranase genetics, Enzyme Stability, Enzymes, Immobilized genetics, Escherichia coli enzymology, Escherichia coli genetics, Glucosyltransferases genetics, Hydrogen-Ion Concentration, Leuconostoc mesenteroides genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Streptococcus mutans genetics, Alginates chemistry, Bacterial Proteins chemistry, Dextranase chemistry, Enzymes, Immobilized chemistry, Glucosyltransferases chemistry, Leuconostoc mesenteroides enzymology, Oligosaccharides chemistry, Pectins chemistry, Streptococcus mutans enzymology

Abstract

The genes for dextransucrase and dextranase were cloned from the genomic regions of Leuconostoc mesenteroides MTCC 10508 and Streptococcus mutans MTCC 497, respectively. Heterologous expression of genes was performed in Escherichia coli. The purified enzyme fractions were entrapped in the alginate-pectin beads. A high immobilization yield of dextransucrase (~ 96%), and dextranase (~ 85%) was achieved. Alginate-pectin immobilization did not affect the optimum temperature and pH of the enzymes; rather, the thermal tolerance and storage stability of the enzymes was improved. The repetitive batch experiments suggested substantially good operational stability of the co-immobilized enzyme system. The synergistic catalytic reactions of alginate-pectin co-entrapped enzyme system were able to produce 7-10 g L -1 oligosaccharides of a high degree of polymerization (DP 3-9) from sucrose (~ 20 g L -1 ) containing feedstocks, e.g., table sugar and cane molasses. The alginate-pectin-based co-immobilized enzyme system is a useful catalytic tool to bioprocess the agro-industrial bio-resource for the production of prebiotic biomolecules.

Published

2019

8. Product solubility control in cellooligosaccharide production by coupled cellobiose and cellodextrin phosphorylase.

Author

Zhong C, Luley-Goedl C, and Nidetzky B

Subjects

Cellulose chemistry, Solubility, Bacterial Proteins chemistry, Cellobiose chemistry, Cellulomonas enzymology, Cellulose analogs & derivatives, Clostridiales enzymology, Dextrins chemistry, Glucosyltransferases chemistry, Oligosaccharides chemistry

Abstract

Soluble cellodextrins (linear β-1,4-d-gluco-oligosaccharides) have interesting applications as ingredients for human and animal nutrition. Their bottom-up synthesis from glucose is promising for bulk production, but to ensure a completely water-soluble product via degree of polymerization (DP) control (DP ≤ 6) is challenging. Here, we show biocatalytic production of cellodextrins with DP centered at 3 to 6 (~96 wt.% of total product) using coupled cellobiose and cellodextrin phosphorylase. The cascade reaction, wherein glucose was elongated sequentially from α-d-glucose 1-phosphate (αGlc1-P), required optimization and control at two main points. First, kinetic and thermodynamic restrictions upon αGlc1-P utilization (200 mM; 45°C, pH 7.0) were effectively overcome (53% → ≥90% conversion after 10 hrs of reaction) by in situ removal of the phosphate released via precipitation with Mg 2+ . Second, the product DP was controlled by the molar ratio of glucose/αGlc1-P (∼0.25; 50 mM glucose) used in the reaction. In optimized conversion, soluble cellodextrins in a total product concentration of 36 g/L were obtained through efficient utilization of the substrates used (glucose: 98%; αGlc1-P: ∼80%) after 1 hr of reaction. We also showed that, by keeping the glucose concentration low (i.e., 1-10 mM; 200 mM αGlc1-P), the reaction was shifted completely towards insoluble product formation (DP ∼9-10). In summary, this study provides the basis for an efficient and product DP-controlled biocatalytic synthesis of cellodextrins from expedient substrates., (© 2019 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals, Inc.)

Published

2019

9. A single mutation in cyclodextrin glycosyltransferase from Paenibacillus barengoltzii changes cyclodextrin and maltooligosaccharides production.

Author

Castillo J, Caminata Landriel S, Sánchez Costa M, Taboga OA, Berenguer J, Hidalgo A, Ferrarotti SA, and Costa H

Subjects

Amino Acid Sequence, Catalytic Domain, Cyclization, Cyclodextrins metabolism, Glucosyltransferases chemistry, Molecular Dynamics Simulation, Oligosaccharides metabolism, Substrate Specificity, Cyclodextrins biosynthesis, Glucosyltransferases genetics, Glucosyltransferases metabolism, Mutagenesis, Site-Directed, Mutation, Oligosaccharides biosynthesis, Paenibacillus enzymology

Abstract

Cyclodextrin glycosyltransferases (CGTases) are bacterial enzymes that catalyze starch conversion into cyclodextrins, which have several biotechnological applications including solubilization of hydrophobic compounds, masking of unpleasant odors and flavors in pharmaceutical preparations, and removal of cholesterol from food. Additionally, CGTases produce maltooligosaccharides, which are linear molecules with potential benefits for human health. Current research efforts are concentrated in the development of engineered enzymes with improved yield and/or particular product specificity. In this work, we analyzed the role of four residues of the CGTase from Paenibacillus barengoltzii as determinants of product specificity. Single mutations were introduced in the CGTase-encoding gene to obtain mutants A137V, A144V, L280A and M329I and the activity of recombinant proteins was evaluated. The residue at position 137 proved to be relevant for CGTase activity. Molecular dynamics studies demonstrated additionally that mutation A137V produces a perturbation in the catalytic site of the CGTase, which correlates with a 10-fold reduction in its catalytic efficiency. Moreover, this mutant showed increased production of maltooligosaccharides with a high degree of polymerization, mostly maltopentaose to maltoheptaose. Our results highlight the role of residue 137 as a determinant of product specificity in this CGTase and may be applied to the rational design of saccharide-producing enzymes., (© The Author(s) 2019. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published

2018

10. Efficient Production of Prebiotic Gluco-oligosaccharides in Orange Juice Using Immobilized and Co-immobilized Dextransucrase.

Author

Tingirikari JMR, Gomes WF, and Rodrigues S

Subjects

Bacterial Proteins chemistry, Citrus sinensis chemistry, Dextranase chemistry, Enzymes, Immobilized chemistry, Fruit and Vegetable Juices, Glucosyltransferases chemistry, Leuconostoc chemistry, Oligosaccharides chemistry, Prebiotics

Abstract

Dextransucrase from Leuconostoc mesenteroides NRRL B-512F was subjected to immobilization and co-immobilization with dextranase from Chaetomium erraticum. Immobilization has enhanced the operational and storage stability of dextransucrase. Two hundred milligrammes (2.4 IU/mg) of alginate beads (immobilized and co-immobilized) were found to be optimum for the production of gluco-oligosaccharides (GOS) in orange juice with a high degree of polymerization. The pulp of the orange juice did not interfere in the reaction. In the batch process, co-immobilized dextransucrase (41 g/L) produced a significantly higher amount of GOS than immobilized dextransucrase (37 g/L). Alginate entrapment enhanced the thermal stability of dextransucrase for up to 3 days in orange juice at 30 °C. The production of GOS in semi-continuous process was 39 g/L in co-immobilized dextransucrase and 33 g/L in immobilized dextransucrase. Thus, immobilization technology offers a great scope in terms of reusability and efficient production of a value added functional health drink.

Published

2017

11. Carbohydrate-binding architecture of the multi-modular α-1,6-glucosyltransferase from Paenibacillus sp. 598K, which produces α-1,6-glucosyl-α-glucosaccharides from starch.

Author

Fujimoto Z, Suzuki N, Kishine N, Ichinose H, Momma M, Kimura A, and Funane K

Subjects

Acarbose chemistry, Apoenzymes chemistry, Apoenzymes genetics, Apoenzymes metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Biocatalysis, Carbohydrate Conformation, Catalytic Domain, Crystallization, Crystallography, X-Ray, Dimerization, Glucosyltransferases chemistry, Glucosyltransferases genetics, Indicators and Reagents chemistry, Ligands, Oligosaccharides chemistry, Protein Conformation, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Terbium chemistry, Acarbose metabolism, Bacterial Proteins metabolism, Glucosyltransferases metabolism, Oligosaccharides metabolism, Paenibacillus enzymology

Abstract

Paenibacillus sp. 598K α-1,6-glucosyltransferase (Ps6TG31A), a member of glycoside hydrolase family 31, catalyzes exo-α-glucohydrolysis and transglucosylation and produces α-1,6-glucosyl-α-glucosaccharides from α-glucan via its disproportionation activity. The crystal structure of Ps6TG31A was determined by an anomalous dispersion method using a terbium derivative. The monomeric Ps6TG31A consisted of one catalytic (β/α) 8 -barrel domain and six small domains, one on the N-terminal and five on the C-terminal side. The structures of the enzyme complexed with maltohexaose, isomaltohexaose, and acarbose demonstrated that the ligands were observed in the catalytic cleft and the sugar-binding sites of four β-domains. The catalytic site was structured by a glucose-binding pocket and an aglycon-binding cleft built by two sidewalls. The bound acarbose was located with its non-reducing end pseudosugar docked in the pocket, and the other moieties along one sidewall serving three subsites for the α-1,4-glucan. The bound isomaltooligosaccharide was found on the opposite sidewall, which provided the space for the acceptor molecule to be positioned for attack of the catalytic intermediate covalent complex during transglucosylation. The N-terminal domain recognized the α-1,4-glucan in a surface-binding mode. Two of the five C-terminal domains belong to the carbohydrate-binding modules family 35 and one to family 61. The sugar complex structures indicated that the first family 35 module preferred α-1,6-glucan, whereas the second family 35 module and family 61 module preferred α-1,4-glucan. Ps6TG31A appears to have enhanced transglucosylation activity facilitated by its carbohydrate-binding modules and substrate-binding cleft that positions the substrate and acceptor sugar for the transglucosylation., (© 2017 The Author(s). Published by Portland Press Limited on behalf of the Biochemical Society.)

Published

2017

12. Paenibacillus sp. 598K 6-α-glucosyltransferase is essential for cycloisomaltooligosaccharide synthesis from α-(1 → 4)-glucan.

Author

Ichinose H, Suzuki R, Miyazaki T, Kimura K, Momma M, Suzuki N, Fujimoto Z, Kimura A, and Funane K

Subjects

Bacillus enzymology, Chromatography, Liquid, Culture Media chemistry, Glucosyltransferases chemistry, Glucosyltransferases genetics, Hydrolysis, Mass Spectrometry, Oligosaccharides chemistry, Paenibacillus genetics, Substrate Specificity, Glucans metabolism, Glucosyltransferases metabolism, Oligosaccharides biosynthesis, Paenibacillus enzymology, Starch metabolism

Abstract

Paenibacillus sp. 598K produces cycloisomaltooligosaccharides (cyclodextrans) from starch even in the absence of dextran. Cycloisomaltooligosaccharide glucanotransferase synthesizes cycloisomaltooligosaccharides exclusively from an α-(1 → 6)-consecutive glucose chain consisting of at least four molecules. Starch is not a substrate of this enzyme. Therefore, we predicted that the bacterium possesses another enzyme system for extending α-(1 → 6)-linked glucoses from starch, which can be used as the substrate for cycloisomaltooligosaccharide glucanotransferase, and identified the transglucosylation enzyme Ps6GT31A. We purified Ps6GT31A from the bacterial culture supernatant, cloned its corresponding gene, and characterized the recombinant enzyme. Ps6GT31A belongs to glycoside hydrolase family 31, and it liberates glucose from the non-reducing end of the substrate in the following order of activity: α-(1 → 4)-> α-(1 → 2)- > α-(1 → 3)- > α-(1 → 6)-glucobiose and maltopentaose > maltotetraose > maltotriose > maltose. Ps6GT31A catalyzes both hydrolysis and transglucosylation. The resulting transglucosylation compounds were analyzed by high-performance liquid chromatography and mass spectrometry. Analysis of the initial products by 13 C nuclear magnetic resonance spectroscopy revealed that Ps6GT31A had a strong α-(1 → 4) to α-(1 → 6) transglucosylation activity. Ps6GT31A elongated α-(1 → 6)-linked glucooligosaccharide to at least a degree of polymerization of 10 through a successive transglucosylation reaction. Eventually, cycloisomaltooligosaccharide glucanotransferase creates cycloisomaltooligosaccharides using the transglucosylation products generated by Ps6GT31A as the substrates. Our data suggest that Ps6GT31A is the key enzyme to synthesize α-(1 → 6)-glucan for cycloisomaltooligosaccharide production in dextran-free environments.

Published

2017

13. Multidimensional Self-Assembled Structures of Alkylated Cellulose Oligomers Synthesized via in Vitro Enzymatic Reactions.

Author

Yataka Y, Sawada T, and Serizawa T

Subjects

Cellulose chemical synthesis, Clostridium thermocellum, Glucosyltransferases chemistry, Glycolipids chemical synthesis, Hydrogels chemistry, Macromolecular Substances chemical synthesis, Micelles, Molecular Structure, Oligosaccharides chemical synthesis, Cellulose chemistry, Glycolipids chemistry, Macromolecular Substances chemistry, Nanostructures chemistry, Oligosaccharides chemistry

Abstract

The self-assembly of biomolecules into highly ordered nano-to-macroscale structures is essential in the construction of biological tissues and organs. A variety of biomolecular assemblies composed of nucleic acids, peptides, and lipids have been used as molecular building units for self-assembled materials. However, crystalline polysaccharides have rarely been utilized in self-assembled materials. In this study, we describe multidimensional self-assembled structures of alkylated cellulose oligomers synthesized via in vitro enzymatic reactions. We found that the alkyl chain length drastically affected the assembled morphologies and allomorphs of cellulose moieties. The modulation of the intermolecular interactions of cellulose oligomers by alkyl substituents was highly effective at controlling their assembly into multidimensional structures. This study proposes a new potential of crystalline oligosaccharides for structural components of molecular assemblies with controlled morphologies and crystal structures.

Published

2016

14. Investigation on the Synthesis of Shigella flexneri Specific Oligosaccharides Using Disaccharides as Potential Transglucosylase Acceptor Substrates.

Author

Salamone S, Guerreiro C, Cambon E, Hargreaves JM, Tarrat N, Remaud-Siméon M, André I, and Mulard LA

Subjects

Biocatalysis, Carbohydrate Sequence, Glucosyltransferases metabolism, Oligosaccharides chemistry, Disaccharides chemistry, Glucosyltransferases chemistry, Oligosaccharides chemical synthesis, Shigella flexneri chemistry

Abstract

Chemo-enzymatic strategies hold great potential for the development of stereo- and regioselective syntheses of structurally defined bioactive oligosaccharides. Herein, we illustrate the potential of the appropriate combination of a planned chemo-enzymatic pathway and an engineered biocatalyst for the multistep synthesis of an important decasaccharide for vaccine development. We report the stepwise investigation, which led to an efficient chemical conversion of allyl α-d-glucopyranosyl-(1→4)-α-l-rhamnopyranosyl-(1→3)-2-deoxy-2-trichloroacetamido-β-d-glucopyranoside, the product of site-specific enzymatic α-d-glucosylation of a lightly protected non-natural disaccharide acceptor, into a pentasaccharide building block suitable for chain elongation at both ends. Successful differentiation between hydroxyl groups features the selective acylation of primary alcohols and acetalation of a cis-vicinal diol, followed by a controlled per-O-benzylation step. Moreover, we describe the successful use of the pentasaccharide intermediate in the [5 + 5] synthesis of an aminoethyl aglycon-equipped decasaccharide, corresponding to a dimer of the basic repeating unit from the O-specific polysaccharide of Shigella flexneri 2a, a major cause of bacillary dysentery. Four analogues of the disaccharide acceptor were synthesized and evaluated to reach a larger repertoire of O-glucosylation patterns encountered among S. flexneri type-specific polysaccharides. New insights on the potential and limitations of planned chemo-enzymatic pathways in oligosaccharide synthesis are provided.

Published

2015

15. Profiling Aglycon-Recognizing Sites of UDP-glucose:glycoprotein Glucosyltransferase by Means of Squarate-Mediated Labeling.

Author

Ohara K, Takeda Y, Daikoku S, Hachisu M, Seko A, and Ito Y

Subjects

Catalytic Domain, Cell Line, Glucosyltransferases genetics, Glucosyltransferases metabolism, Humans, Oligosaccharides metabolism, Staining and Labeling methods, Uridine Diphosphate metabolism, Glucosyltransferases chemistry, Oligosaccharides chemistry, Uridine Diphosphate chemistry

Abstract

Because of its ability to selectively glucosylate misfolded glycoproteins, UDP-glucose:glycoprotein glucosyltransferase (UGGT) functions as a folding sensor in the glycoprotein quality control system in the endoplasmic reticulum (ER). The unique property of UGGT derives from its ability to transfer a glucose residue to N-glycan moieties of incompletely folded glycoproteins. We have previously discovered nonproteinic synthetic substrates of this enzyme, allowing us to conduct its high-sensitivity assay in a quantitative manner. In this study, we aimed to conduct site-selective affinity labeling of UGGT using a functionalized oligosaccharide probe to identify domain(s) responsible for recognition of the aglycon moiety of substrates. To this end, a probe 1 was designed to selectively label nucleophilic amino acid residues in the proximity of the canonical aglycon-recognizing site of human UGGT1 (HUGT1) via squaramide formation. As expected, probe 1 was able to label HUGT1 in the presence of UDP. Analysis by nano-LC-ESI/MS(n) identified a unique lysine residue (K1424) that was modified by 1. Kyte-Doolittle analysis as well as homology modeling revealed a cluster of hydrophobic amino acids that may be functional in the folding sensing mechanism of HUGT1.

Published

2015

16. Enzymatic Synthesis of Quercetin Monoglucopyranoside and Maltooligosaccharides.

Author

Yasukawa R, Moriwaki N, Uesugi D, Kaneko F, Hamada H, and Ozaki S

Subjects

Biocatalysis, Molecular Structure, Glucosides chemistry, Glucosyltransferases chemistry, Oligosaccharides chemistry, Phytolacca americana enzymology, Plant Proteins chemistry, Quercetin chemistry

Abstract

Quercetin 3-O-β-monoglucopyranoside and quercetin 3-O-β-maltooligosaccharide were synthesized from quercetin using glucosyltransferase-3 from Phytolacca americana and cyclodextrin glucanotransferase.

Published

2015

17. Molecular engineering of cycloisomaltooligosaccharide glucanotransferase from Bacillus circulans T-3040: structural determinants for the reaction product size and reactivity.

Author

Suzuki R, Suzuki N, Fujimoto Z, Momma M, Kimura K, Kitamura S, Kimura A, and Funane K

Subjects

Bacillus enzymology, Bacillus genetics, Mutation, Missense, Protein Structure, Tertiary, Structure-Activity Relationship, Amino Acid Substitution, Bacterial Proteins chemistry, Bacterial Proteins genetics, Glucosyltransferases chemistry, Glucosyltransferases genetics, Mutagenesis, Site-Directed, Oligosaccharides biosynthesis, Oligosaccharides chemistry, Oligosaccharides genetics

Abstract

Cycloisomaltooligosaccharide glucanotransferase (CITase) is a member of glycoside hydrolase family 66 and it produces cycloisomaltooligosaccharides (CIs). Small CIs (CI-7-9) and large CIs (CI-≥10) are designated as oligosaccharide-type CIs (oligo-CIs) and megalosaccharide-type CIs (megalo-CIs) respectively. CITase from Bacillus circulans T-3040 (BcCITase) produces mainly CI-8 with little megalo-CIs. It has two family 35 carbohydrate-binding modules (BcCBM35-1 and BcCBM35-2). BcCBM35-1 is inserted in a catalytic domain of BcCITase and BcCBM35-2 is located at the C-terminal region. Our previous studies suggested that BcCBM35-1 has two substrate-binding sites (B-1 and B-2) [Suzuki et al. (2014) J. Biol. Chem. 289, 12040-12051]. We implemented site-directed mutagenesis of BcCITase to explore the preference for product size on the basis of the 3D structure of BcCITase. Mutational studies provided evidence that B-1 and B-2 contribute to recruiting substrate and maintaining product size respectively. A mutant (mutant-R) with four mutations (F268V, D469Y, A513V and Y515S) produced three times as much megalo-CIs (CI-10-12) and 1.5 times as much total CIs (CI-7-12) as compared with the wild-type (WT) BcCITase. The 3D structure of the substrate-enzyme complex of mutant-R suggested that the modified product size specificity was attributable to the construction of novel substrate-binding sites in the B-2 site of BcCBM35-1 and reactivity was improved by mutation on subsite -3 on the catalytic domain.

Published

2015

18. Programmed chemo-enzymatic synthesis of the oligosaccharide component of a carbohydrate-based antibacterial vaccine candidate.

Author

Salamone S, Guerreiro C, Cambon E, André I, Remaud-Siméon M, and Mulard LA

Subjects

Bacterial Vaccines chemistry, Carbohydrate Conformation, Carbohydrate Sequence, Glucosyltransferases chemistry, Glycosylation, Haptens biosynthesis, Haptens chemistry, Molecular Sequence Data, Oligosaccharides chemistry, Sucrose metabolism, Bacterial Vaccines biosynthesis, Bacterial Vaccines chemical synthesis, Dysentery, Bacillary prevention & control, Glucosyltransferases metabolism, Oligosaccharides biosynthesis, Oligosaccharides chemical synthesis, Sucrose chemistry

Abstract

The powerful chemo-enzymatic synthesis of the pentadecasaccharide hapten involved in the first synthetic carbohydrate-based vaccine candidate against endemic shigellosis is reported. The high yielding site-selective α-D-glucosylation of a lightly protected disaccharide by an engineered transglucosylase-sucrose system gave a trisaccharide, which was chemically elongated by an efficient [5+5] process.

Published

2015

19. Essential role of amino acid position 226 in oligosaccharide elongation by amylosucrase from Neisseria polysaccharea.

Author

Cambon E, Barbe S, Pizzut-Serin S, Remaud-Simeon M, and André I

Subjects

Amino Acid Substitution, Amino Acids genetics, Catalytic Domain, DNA Mutational Analysis, Glucosyltransferases chemistry, Glucosyltransferases genetics, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Mutant Proteins chemistry, Mutant Proteins genetics, Mutant Proteins metabolism, Neisseria genetics, Protein Conformation, Sucrose metabolism, Amino Acids metabolism, Glucosyltransferases metabolism, Neisseria enzymology, Oligosaccharides metabolism

Abstract

Amylosucrase from Neisseria polysaccharea is a remarkable transglucosylase that synthesizes an insoluble amylose-like polymer from sole substrate sucrose. One particular amino acid, Arg226, was proposed from molecular modeling studies to play an important role in the formation of the active site topology and in the accessibility of ligands to the catalytic site. The systematic mutation of this Arg residue by all 19 other possible amino acids revealed that all single-mutants had a higher activity on sucrose compared to the wild-type enzyme. An extensive kinetic investigation showed that catalytic efficiencies are greatly impacted by the presence of natural acceptors in the reaction media, their chain length and the nature of the amino acid at position 226. Compared to the wild-type enzyme, the R226N mutant showed a 10-fold enhancement in the catalytic efficiency and a nearly twofold higher production of an insoluble amylose-like polymer that can be of interest for biotechnological applications., (© 2014 Wiley Periodicals, Inc.)

Published

2014

20. Conformation and physical properties of cycloisomaltooligosaccharides in aqueous solution.

Author

Suzuki S, Yukiyama T, Ishikawa A, Yuguchi Y, Funane K, and Kitamura S

Subjects

Cyclization, Dextrans chemistry, Glucosyltransferases chemistry, Models, Molecular, Molecular Conformation, Oligosaccharides isolation & purification, Scattering, Small Angle, Viscosity, X-Ray Diffraction, Oligosaccharides chemistry, Water chemistry

Abstract

We studied the conformation and physical properties of cyclic and linear isomaltooligosaccharides in aqueous solution by intrinsic viscosity measurement, small angle X-ray scattering (SAXS) and molecular modeling. We used four cycloisomaltooligosaccharide samples (CIs) with degree of polymerization (DP) 7-10 (CI-7-CI-10) and five linear isomaltooligosaccharide samples (LIs) with DP 7-11 (LI-7-LI-11). The values of α in the Mark-Houwink-Sakurada equation [η]=KM(w)(α) for the CI and LI were determined to be 0.50 and 0.78, respectively. The radii of gyration (R(G)) of CI-7, CI-8, CI-9 and CI-10 determined from SAXS data were 6.7, 6.9, 7.5 and 8.3Å, respectively. The scattering profile of CI-9 compared with those obtained for molecular models indicated that CI molecular chains are less flexible than those for LIs and adopt a rather compact circular conformation., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2014

21. Structural enzymology of Cellvibrio japonicus Agd31B protein reveals α-transglucosylase activity in glycoside hydrolase family 31.

Author

Larsbrink J, Izumi A, Hemsworth GR, Davies GJ, and Brumer H

Subjects

Bacterial Proteins metabolism, Catalytic Domain, Crystallography, X-Ray, Glucosyltransferases metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Oligosaccharides metabolism, Structure-Activity Relationship, Bacterial Proteins chemistry, Cellvibrio enzymology, Glucosyltransferases chemistry, Oligosaccharides chemistry

Abstract

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.

Published

2012

22. Structural characterization of linear isomalto-/malto-oligomer products synthesized by the novel GTFB 4,6-α-glucanotransferase enzyme from Lactobacillus reuteri 121.

Author

Dobruchowska JM, Gerwig GJ, Kralj S, Grijpstra P, Leemhuis H, Dijkhuizen L, and Kamerling JP

Subjects

Carbohydrate Conformation, Carbohydrate Sequence, Chromatography, Ion Exchange, Glucans chemistry, Glycosylation, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Oligosaccharides chemistry, Oligosaccharides isolation & purification, Recombinant Proteins chemistry, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Sugar Alcohols chemistry, Trisaccharides chemistry, Bacterial Proteins chemistry, Glucosyltransferases chemistry, Limosilactobacillus reuteri enzymology, Maltose chemistry, Oligosaccharides chemical synthesis

Abstract

Recently, a novel glucansucrase (GS)-like gene (gtfB) was isolated from the probiotic bacterium Lactobacillus reuteri 121 and expressed in Escherichia coli. The purified recombinant GTFB enzyme was characterized and turned out to be inactive with sucrose, the natural GS substrate. Instead, GTFB acted on malto-oligosaccharides (MOSs), thereby yielding elongated gluco-oligomers/polymers containing besides (α1 → 4) also (α1 → 6) glycosidic linkages, and it was classified as a 4,6-α-glucanotransferase. To gain more insight into its reaction specificity, incubations of the GTFB enzyme with a series of MOSs and their corresponding alditols [degree of polymerization, DP2(-ol)-DP7(-ol)] were carried out, and (purified) products were structurally analyzed with matrix-assisted laser desorption ionization time-of-flight mass spectrometry and one-/two-dimensional (1)H and (13)C nuclear magnetic resonance spectroscopy. With each of the tested malto-oligomers, the GTFB enzyme yielded series of novel linear isomalto-/malto-oligomers, in the case of DP7 up to DP >35.

Published

2012

23. Kinetic inhibition of human salivary alpha-amylase by a novel cellobiose-containing tetrasaccharide.

Author

Rudeekulthamrong P and Kaulpiboon J

Subjects

Cellobiose chemistry, Chromatography, High Pressure Liquid, Enzyme Inhibitors chemical synthesis, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Humans, Hydrogen-Ion Concentration, Oligosaccharides chemical synthesis, Temperature, beta-Cyclodextrins chemistry, Enzyme Inhibitors pharmacokinetics, Oligosaccharides pharmacokinetics, Saliva enzymology, alpha-Amylases antagonists & inhibitors

Abstract

Objective: The aim of the study was to evaluate the inhibitory kinetics of a novel cellobiose-containing tetrasaccharide on human salivary alpha-amylase (HSA)., Material and Method: Synthesis of cellobiose-containing tetrasaccharide was catalyzed by Paenibacillus sp. All CGTase using beta-CD as a donor and cellobiose as an acceptor under the optimal conditions. The reaction mixture was analyzed by HPLC and a cellobiose-containing tetrasaccharide obtained was studied for its inhibitory kinetics., Results: In vitro activity of human salivary alpha-amylase showed the optimum pH and temperature at 7.0 and 37 degrees C, respectively. The effects of metal ions, protective chemicals and saccharides on alpha-amylase activity, they were found that 10 mM concentration of CaCl2 and NaCl enhanced the enzyme activity. In contrast, the enzyme activity was significantly inhibited by 10 mM of HgCI2, alpha-cyclodextrin (alpha-CD) and synthetic cellobiose-containing tetrasaccharide. Chemicals often used as protective substance for enzyme such as beta-mercaptoethanol, EDTA or used as fungicide during enzyme purification (NaN3) had no effect on the activity of this enzyme. As a cellobiose-containing tetrasaccharide was shown to have a pronounce inhibition on alpha-amylase activity. Its inhibition kinetic was performed and found that cellobiose-containing tetrasaccharide was a competitive inhibitor with a Ki value of 7.89 microM., Conclusion: Inhibition kinetic of a cellobiose-containing tetrasaccharide on alpha-amylase activity was competitive type with Ki value of 7.89 microM. In addition, these results will be a basic knowledge in controlling alpha-amylase actions that have influence on blood glucose level of trial animal and human further

Published

2012

24. Apo- and cellopentaose-bound structures of the bacterial cellulose synthase subunit BcsZ.

Author

Mazur O and Zimmer J

Subjects

Apoenzymes chemistry, Catalytic Domain, Crystallography, X-Ray, Escherichia coli Proteins metabolism, Glucosyltransferases metabolism, Oligosaccharides metabolism, Protein Structure, Quaternary, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Glucosyltransferases chemistry, Oligosaccharides chemistry

Abstract

Cellulose, a very abundant extracellular polysaccharide, is synthesized in a finely tuned process that involves the activity of glycosyl-transferases and hydrolases. The cellulose microfibril consists of bundles of linear β-1,4-glucan chains that are synthesized inside the cell; however, the mechanism by which these polymers traverse the cell membrane is currently unknown. In Gram-negative bacteria, the cellulose synthase complex forms a trans-envelope complex consisting of at least four subunits. Although three of these subunits account for the synthesis and translocation of the polysaccharide, the fourth subunit, BcsZ, is a periplasmic protein with endo-β-1,4-glucanase activity. BcsZ belongs to family eight of glycosyl-hydrolases, and its activity is required for optimal synthesis and membrane translocation of cellulose. In this study we report two crystal structures of BcsZ from Escherichia coli. One structure shows the wild-type enzyme in its apo form, and the second structure is for a catalytically inactive mutant of BcsZ in complex with the substrate cellopentaose. The structures demonstrate that BcsZ adopts an (α/α)(6)-barrel fold and that it binds four glucan moieties of cellopentaose via highly conserved residues exclusively on the nonreducing side of its catalytic center. Thus, the BcsZ-cellopentaose structure most likely represents a posthydrolysis state in which the newly formed nonreducing end has already left the substrate binding pocket while the enzyme remains attached to the truncated polysaccharide chain. We further show that BcsZ efficiently degrades β-1,4-glucans in in vitro cellulase assays with carboxymethyl-cellulose as substrate., (© 2011 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2011

25. Efficient chemoenzymatic oligosaccharide synthesis by reverse phosphorolysis using cellobiose phosphorylase and cellodextrin phosphorylase from Clostridium thermocellum.

Author

Nakai H, Hachem MA, Petersen BO, Westphal Y, Mannerstedt K, Baumann MJ, Dilokpimol A, Schols HA, Duus JØ, and Svensson B

Subjects

Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites genetics, Biocatalysis, Cellobiose biosynthesis, Cellobiose chemistry, Cellulose analogs & derivatives, Cellulose biosynthesis, Cellulose chemistry, Chromatography, High Pressure Liquid, Clostridium thermocellum genetics, Clostridium thermocellum metabolism, Dextrins biosynthesis, Dextrins chemistry, Enzyme Stability, Glucosyltransferases chemistry, Glucosyltransferases genetics, Hydrogen-Ion Concentration, Models, Molecular, Molecular Sequence Data, Molecular Structure, Oligosaccharides chemistry, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Stereoisomerism, Temperature, Bacterial Proteins metabolism, Clostridium thermocellum enzymology, Glucosyltransferases metabolism, Oligosaccharides biosynthesis

Abstract

Inverting cellobiose phosphorylase (CtCBP) and cellodextrin phosphorylase (CtCDP) from Clostridium thermocellum ATCC27405 of glycoside hydrolase family 94 catalysed reverse phosphorolysis to produce cellobiose and cellodextrins in 57% and 48% yield from α-d-glucose 1-phosphate as donor with glucose and cellobiose as acceptor, respectively. Use of α-d-glucosyl 1-fluoride as donor increased product yields to 98% for CtCBP and 68% for CtCDP. CtCBP showed broad acceptor specificity forming β-glucosyl disaccharides with β-(1→4)- regioselectivity from five monosaccharides as well as branched β-glucosyl trisaccharides with β-(1→4)-regioselectivity from three (1→6)-linked disaccharides. CtCDP showed strict β-(1→4)-regioselectivity and catalysed linear chain extension of the three β-linked glucosyl disaccharides, cellobiose, sophorose, and laminaribiose, whereas 12 tested monosaccharides were not acceptors. Structure analysis by NMR and ESI-MS confirmed two β-glucosyl oligosaccharide product series to represent novel compounds, i.e. β-D-glucopyranosyl-[(1→4)-β-D-glucopyranosyl](n)-(1→2)-D-glucopyranose, and β-D-glucopyranosyl-[(1→4)-β-D-glucopyranosyl](n)-(1→3)-D-glucopyranose (n = 1-7). Multiple sequence alignment together with a modelled CtCBP structure, obtained using the crystal structure of Cellvibrio gilvus CBP in complex with glucose as a template, indicated differences in the subsite +1 region that elicit the distinct acceptor specificities of CtCBP and CtCDP. Thus Glu636 of CtCBP recognized the C1 hydroxyl of β-glucose at subsite +1, while in CtCDP the presence of Ala800 conferred more space, which allowed accommodation of C1 substituted disaccharide acceptors at the corresponding subsites +1 and +2. Furthermore, CtCBP has a short Glu496-Thr500 loop that permitted the C6 hydroxyl of glucose at subsite +1 to be exposed to solvent, whereas the corresponding longer loop Thr637-Lys648 in CtCDP blocks binding of C6-linked disaccharides as acceptors at subsite +1. High yields in chemoenzymatic synthesis, a novel regioselectivity, and novel oligosaccharides including products of CtCDP catalysed oligosaccharide oligomerisation using α-d-glucosyl 1-fluoride, all together contribute to the formation of an excellent basis for rational engineering of CBP and CDP to produce desired oligosaccharides., (Copyright © 2010 Elsevier Masson SAS. All rights reserved.)

Published

2010

26. Enzyme synthesis of oligosaccharides using cashew apple juice as substrate.

Author

Rabelo MC, Fontes CP, and Rodrigues S

Subjects

Anacardium, Carbohydrates chemistry, Food Industry, Glucosyltransferases chemistry, Glycerol chemistry, Hydrogen-Ion Concentration, Leuconostoc metabolism, Malus, Oligosaccharides metabolism, Surface Properties, Agriculture methods, Biotechnology methods, Oligosaccharides chemistry

Abstract

The use of agriculture substrates in industrial biotechnological processes has been increasing because of their low cost. In this work, the use of clarified cashew apple juice was investigated as substrate for enzyme synthesis of prebiotic oligosaccharide. The results showed that cashew apple juice is a good source of reducing sugars and can be used as substrate for the production of dextransucrase by Leuconostoc citreum B-742 for the synthesis of oligosaccharides using the crude enzyme. Optimal oligosaccharide yield (approximately 80%) was obtained for sucrose concentrations lower than 60 g/L and reducing sugar concentrations higher than 100 g/L.

Published

2009

27. Optimization of oligosaccharide synthesis from cellobiose by dextransucrase.

Author

Kim M and Day DF

Subjects

Computer Simulation, Quality Control, Cellobiose chemistry, Combinatorial Chemistry Techniques methods, Glucosyltransferases chemistry, Leuconostoc enzymology, Models, Chemical, Oligosaccharides chemical synthesis

Abstract

There is a growing market for oligosaccharides as sweeteners, prebiotics, anticariogenic compounds, and immunostimulating agents in both food and pharmaceutical industries. Interest in novel carbohydrate-based products has grown because of their reduced toxicity and low immune response. Cellobiose is potentially valuable as a nondigestible sugar. The reaction of cellobiose, as an acceptor with a sucrose as a donor, catalyzed by a dextransucrase from Leuconostoc mesenteroides B-512FMCM, produced a series of cellobio-oligosaccharides. This production system was optimized using a Box-Behnken experimental design for 289 mM of sucrose and 250 mM of cellobiose and 54 U of the enzyme at pH 5.2 and 30 degrees C, to produce maximum yields of oligosaccharide.

Published

2008

28. One-pot synthesis of a pentasaccharide with antibiotic activity against Helicobacter pylori.

Author

Wang P, Lee H, Fukuda M, and Seeberger PH

Subjects

Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Carbohydrate Sequence, Enzyme Activation drug effects, Glucosyltransferases antagonists & inhibitors, Glucosyltransferases chemistry, Glycosylation, Helicobacter pylori enzymology, Molecular Sequence Data, Oligosaccharides chemistry, Oligosaccharides pharmacology, Anti-Bacterial Agents chemical synthesis, Oligosaccharides chemical synthesis

Abstract

A pentasaccharide that contains the alpha-1,4-GlcNAc mucin core two-branched O-glycan has been synthesized by a one-pot, two-step glycosylation strategy; this particular carbohydrate motif may provide protection against H. pylonri induced pathologies since the synthetic pentasaccharide inhibits cholesterol alpha-glucosyltransferase (IC50 of 0.47 mM).

Published

2007

29. Penta-, hexa-, and heptasaccharide acceptor products of alternansucrase.

Author

Côté GL and Sheng S

Subjects

Carbohydrate Sequence, Chromatography, High Pressure Liquid, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Glycosyltransferases chemistry, Magnetic Resonance Spectroscopy, Maltose chemistry, Maltose metabolism, Models, Chemical, Molecular Sequence Data, Molecular Structure, Oligosaccharides chemistry, Sucrose chemistry, Sucrose metabolism, Glycosyltransferases metabolism, Oligosaccharides metabolism

Abstract

In the presence of suitable acceptor molecules, dextransucrase makes a homologous series of oligosaccharides in which the isomers differ by a single glucosyl unit, whereas alternansucrase synthesizes one trisaccharide, two tetrasaccharides, etc. For the example of maltose as the acceptor, if one considers only the linear, unbranched possibilities for alternansucrase, the hypothetical number of potential products increases exponentially as a function of the degree of polymerization (DP). Experimental evidence indicates that far fewer products are actually formed. We show that only certain isomers of DP >4 are formed from maltose in measurable amounts, and that these oligosaccharides belong to the oligoalternan series rather than the oligodextran series. When the oligosaccharide acceptor products from maltose were separated by size-exclusion chromatography and HPLC, only one pentasaccharide was isolated. Its structure was alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc. Two hexasaccharides were formed in approximately equal quantities: alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc and alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc. Just one heptasaccharide was isolated from the reaction mixture, alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->4)-D-Glc. We conclude that the enzyme is incapable of forming two consecutive alpha-(1-->3) linkages, and does not form products with more than two consecutive alpha-(1-->6) linkages. The distribution of products may be kinetically determined.

Published

2006

30. A novel glucanotransferase from a Bacillus circulans strain that produces a cyclomaltopentaose cyclized by an alpha-1,6-linkage.

Author

Watanabe H, Nishimoto T, Mukai K, Kubota M, Chaen H, and Fukuda S

Subjects

Amino Acid Sequence, Amylose chemistry, Cyclization, Dimerization, Glucans chemistry, Glucosyltransferases genetics, Glucosyltransferases isolation & purification, Hydrogen-Ion Concentration, Molecular Sequence Data, Oligosaccharides chemistry, Substrate Specificity, Temperature, Time Factors, Bacillus enzymology, Glucosyltransferases chemistry, Oligosaccharides biosynthesis

Abstract

A novel glucanotransferase, involved in the synthesis of a cyclomaltopentaose cyclized by an alpha-1,6-linkage [ICG5; cyclo-{-->6)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->4)-alpha-D-Glcp-(1-->}], from starch, was purified to homogeneity from the culture supernatant of Bacillus circulans AM7. The pI was estimated to be 7.5. The molecular mass of the enzyme was estimated to be 184 kDa by gel filtration and 106 kDa by SDS-PAGE. These results suggest that the enzyme forms a dimer structure. It was most active at pH 4.5 to 8.0 at 50 degrees C, and stable from pH 4.5 to 9.0 at up to 35 degrees C. The addition of 1 mM Ca(2+) enhanced the thermal stability of the enzyme up to 40 degrees C. It acted on maltooligosaccharides that have degrees of polymerization of 3 or more, amylose, and soluble starch, to produce ICG5 by an intramolecular alpha-1,6-glycosyl transfer reaction. It also catalyzed the transfer of part of a linear oligosaccharide to another oligosaccharide by an intermolecular alpha-1,4-glycosyl transfer reaction. Thus the ICG5-forming enzyme was found to be a novel glucanotransferase. We propose isocyclomaltooligosaccharide glucanotransferase (IGTase) as the trivial name of this enzyme.

Published

2006

31. Purification, characterization, and gene cloning of a novel maltosyltransferase from an Arthrobacter globiformis strain that produces an alternating alpha-1,4- and alpha-1,6-cyclic tetrasaccharide from starch.

Author

Mukai K, Watanabe H, Kubota M, Chaen H, Fukuda S, and Kurimoto M

Subjects

Amino Acid Sequence, Base Sequence, Chromatography, High Pressure Liquid, Cloning, Molecular, DNA, Bacterial genetics, Enzyme Stability, Genes, Bacterial, Glucosyltransferases chemistry, Hydrogen-Ion Concentration, Kinetics, Models, Biological, Molecular Sequence Data, Molecular Weight, Oligosaccharides chemistry, Sequence Homology, Amino Acid, Soil Microbiology, Substrate Specificity, Arthrobacter enzymology, Arthrobacter genetics, Glucosyltransferases genetics, Glucosyltransferases metabolism, Oligosaccharides biosynthesis, Starch metabolism

Abstract

A glycosyltransferase, involved in the synthesis of cyclic maltosylmaltose [CMM; cyclo-{-->6)-alpha-D-Glcp(1-->4)-alpha-D-Glcp(1-->6)-alpha-D-Glcp(1-->4)-alpha-D-Glcp(1-->}] from starch, was purified to homogeneity from the culture supernatant of Arthrobacter globiformis M6. The CMM-forming enzyme had a molecular mass of 71.7 kDa and a pI of 3.6. The enzyme was most active at pH 6.0 and 50 degrees C and was stable from pH 5.0 to 9.0 and up to 30 degrees C. The addition of 1 mM Ca2+ enhanced the thermal stability of the enzyme up to 45 degrees C. The enzyme acted on maltooligosaccharides that have degrees of polymerization of > or =3, amylose, and soluble starch to produce CMM but failed to act on cyclomaltodextrins, pullulan, and dextran. The mechanism for the synthesis of CMM from maltotetraose was determined as follows: (i) maltotetraose + maltotetraose --> 6(4)-O-alpha-maltosyl-maltotetraose + maltose and (ii) 6(4)-O-alpha-maltosyl-maltotetraose --> CMM + maltose. Thus, the CMM-forming enzyme was found to be a novel maltosyltransferase (6MT) catalyzing both intermolecular and intramolecular alpha-1,6-maltosyl transfer reactions. The gene for 6MT, designated cmmA, was isolated from a genomic library of A. globiformis M6. The cmmA gene consisted of 1,872 bp encoding a signal peptide of 40 amino acids and a mature protein of 583 amino acids with a calculated molecular mass of 64,637. The deduced amino acid sequence showed similarities to alpha-amylase and cyclomaltodextrin glucanotransferase. The four conserved regions common in the alpha-amylase family enzymes were also found in 6MT, indicating that 6MT should be assigned to this family.

Published

2006

32. Chemoenzymatic synthesis of 6omega -modified maltooligosaccharides from cyclodextrin derivatives.

Author

Fraschini C, Greffe L, Driguez H, and Vignon MR

Subjects

Carbohydrate Conformation, Carbohydrate Sequence, Carbohydrates chemistry, Chromatography, Thin Layer, Glucan 1,4-alpha-Glucosidase chemistry, Glucose chemistry, Glucosyltransferases chemistry, Hydrolysis, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Oligosaccharides chemistry, Trisaccharides chemistry, Cyclodextrins chemistry, Oligosaccharides chemical synthesis

Abstract

Regioselectively substituted maltooligosaccharides were prepared by enzymatic transformation of modified cyclodextrins by using simultaneously two different enzymes: cyclodextrin glucanotransferase (CGTase) and amyloglucosidase. Oligosaccharides were obtained in very good yields and their structures were identified by 1D and 2D NMR spectroscopy. These results provided new information about the specificity of the catalytic sites of CGTase and amyloglucosidase. They also offered new ways for the synthesis of regioselectively modified maltooligosaccharides.

Published

2005

33. Modified oligosaccharides as potential dental plaque control materials.

Author

Seo ES, Kim D, Robyt JF, Day DF, Kim DW, Park HJ, and Park HJ

Subjects

Animals, Cell Proliferation drug effects, Coculture Techniques, Dental Plaque drug therapy, Enzyme Activation, Enzyme Inhibitors administration & dosage, Enzyme Inhibitors chemistry, Glucosyltransferases biosynthesis, Humans, Hydrogen-Ion Concentration, Leuconostoc physiology, Mouth microbiology, Saccharomycetales physiology, Streptococcus physiology, Glucosyltransferases antagonists & inhibitors, Glucosyltransferases chemistry, Leuconostoc drug effects, Oligosaccharides administration & dosage, Oligosaccharides chemistry, Saccharomycetales drug effects, Streptococcus drug effects

Abstract

Metabolic acids produced by oral pathogens demineralize tooth surfaces, leading to dental caries. Glucosyltransferases are the key factor in this process. We synthesized various modified oligosaccharides and tested them for their inhibitory effects on glucosyltransferase activity. Oligosaccharides were produced using a mixed-culture fermentation of Lipomyces starkeyi and Leuconostoc mesenteroides and then further modified as iron- and sulfate-oligosaccharides. Iron- and sulfate-oligosaccharides reduced glucosyltransferase activity of Streptococci from 17% to 43% and prevented the formation of insoluble biomass on the surface of glass vials or stainless steel wires in the presence of sucrose. They also reduced the growth and acid productions of oral pathogens including S. mutans, S. sobrinus, Eikenella corrodens, Prevotella intermedia, and Actinobacillus actinomycetemcmitans.

Published

2004

34. Capillary electrophoresis analysis of glucooligosaccharide regioisomers.

Author

Joucla G, Brando T, Remaud-Simeon M, Monsan P, and Puzo G

Subjects

Amination, Carbohydrate Sequence, Glucosyltransferases chemistry, Isomerism, Leuconostoc enzymology, Maltose chemistry, Mass Spectrometry, Molecular Sequence Data, Oligosaccharides chemical synthesis, Oligosaccharides chemistry, Pyrenes chemistry, Sucrose chemistry, Sulfonic Acids chemistry, Electrophoresis, Capillary methods, Glucose chemistry, Glucosyltransferases metabolism, Oligosaccharides isolation & purification

Abstract

Complex gluco-oligosaccharide mixtures of two regioisomer series were successfully separated by CE. The gluco-oligosaccharide series were synthesized, employing a dextransucrase from Leuconostoc mesenteroides NRRL B-512F, by successive glucopyranosyl transfers from sucrose to the acceptor glucose or maltose. The glucosyl transfer to both acceptors, occurring through the formation of alpha1-->6 linkages, differed for the two series only in the glucosidic bond to the reducing end namely alpha1-->6 or alpha1-->4 bond for glucose or maltose acceptor, respectively. Thus, the combination of the two series results in mixed pairs of gluco-oligosaccharide regioisomers with different degrees of polymerization (DP). These regioisomer series were first derivatized by reductive amination with 9-aminopyrene-1,4,6-trisulfonate (APTS). Under acidic conditions using triethyl ammonium acetate as electrolyte, the APTS-gluco-oligosaccharides of each series were separated enabling unambiguous size determination by coupling CE to electrospray-mass spectrometry. However, neither these acidic conditions nor alkaline buffer systems could be adapted for the separation of the gluco-oligosaccharide regioisomers arising from the two combined series. By contrast, increased resolution was observed in an alkaline borate buffer, using differential complexation of the regioisomers with the borate anions. Such conditions were also successfully applied to the separation of glucodisaccharide regioisomers composed of alpha1-->2, alpha1-->3, alpha1-->4, and alpha1-->6 linkages commonly synthesized by glucansucrase enzymes.

Published

2004

35. Molecular basis of the amylose-like polymer formation catalyzed by Neisseria polysaccharea amylosucrase.

Author

Albenne C, Skov LK, Mirza O, Gajhede M, Feller G, D'Amico S, André G, Potocki-Véronèse G, van der Veen BA, Monsan P, and Remaud-Simeon M

Subjects

Amino Acid Sequence, Amino Acid Substitution, Binding Sites, Conserved Sequence, Glucosyltransferases isolation & purification, Models, Molecular, Mutagenesis, Site-Directed, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Sucrose metabolism, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Neisseria enzymology, Oligosaccharides metabolism

Abstract

Amylosucrase from Neisseria polysaccharea is a remarkable transglucosidase from family 13 of the glycoside-hydrolases that synthesizes an insoluble amylose-like polymer from sucrose in the absence of any primer. Amylosucrase shares strong structural similarities with alpha-amylases. Exactly how this enzyme catalyzes the formation of alpha-1,4-glucan and which structural features are involved in this unique functionality existing in family 13 are important questions still not fully answered. Here, we provide evidence that amylosucrase initializes polymer formation by releasing, through sucrose hydrolysis, a glucose molecule that is subsequently used as the first acceptor molecule. Maltooligosaccharides of increasing size were produced and successively elongated at their nonreducing ends until they reached a critical size and concentration, causing precipitation. The ability of amylosucrase to bind and to elongate maltooligosaccharides is notably due to the presence of key residues at the OB1 acceptor binding site that contribute strongly to the guidance (Arg415, subsite +4) and the correct positioning (Asp394 and Arg446, subsite +1) of acceptor molecules. On the other hand, Arg226 (subsites +2/+3) limits the binding of maltooligosaccharides, resulting in the accumulation of small products (G to G3) in the medium. A remarkable mutant (R226A), activated by the products it forms, was generated. It yields twice as much insoluble glucan as the wild-type enzyme and leads to the production of lower quantities of by-products.

Published

2004

36. Effects of essential carbohydrate/aromatic stacking interaction with Tyr100 and Phe259 on substrate binding of cyclodextrin glycosyltransferase from alkalophilic Bacillus sp. 1011.

Author

Haga K, Kanai R, Sakamoto O, Aoyagi M, Harata K, and Yamane K

Subjects

Acarbose chemistry, Amino Acid Sequence, Binding Sites genetics, Crystallography, X-Ray, Glucosyltransferases genetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Phenylalanine genetics, Protein Binding genetics, Structure-Activity Relationship, Substrate Specificity, Tyrosine genetics, Bacillus enzymology, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Oligosaccharides chemistry, Phenylalanine chemistry, Tyrosine chemistry

Abstract

The stacking interaction between a tyrosine residue and the sugar ring at the catalytic subsite -1 is strictly conserved in the glycoside hydrolase family 13 enzymes. Replacing Tyr100 with leucine in cyclodextrin glycosyltransferase (CGTase) from Bacillus sp. 1011 to prevent stacking significantly decreased all CGTase activities. The adjacent stacking interaction with both Phe183 and Phe259 onto the sugar ring at subsite +2 is essentially conserved among CGTases. F183L/F259L mutant CGTase affects donor substrate binding and/or acceptor binding during transglycosylation [Nakamura et al. (1994) Biochemistry 33, 9929-9936]. To elucidate the precise role of carbohydrate/aromatic stacking interaction at subsites -1 and +2 on the substrate binding of CGTases, we analyzed the X-ray structures of wild-type (2.0 A resolution), and Y100L (2.2 A resolution) and F183L/F259L mutant (1.9 A resolution) CGTases complexed with the inhibitor, acarbose. The refined structures revealed that acarbose molecules bound to the Y100L mutant moved from the active center toward the side chain of Tyr195, and the hydrogen bonding and hydrophobic interaction between acarbose and subsites significantly diminished. The position of pseudo-tetrasaccharide binding in the F183L/F259L mutant was closer to the non-reducing end, and the torsion angles of glycosidic linkages at subsites -1 to +1 on molecule 1 and subsites -2 to -1 on molecule 2 significantly changed compared with that of each molecule of wild-type-acarbose complex to adopt the structural change of subsite +2. These structural and biochemical data suggest that substrate binding in the active site of CGTase is critically affected by the carbohydrate/aromatic stacking interaction with Tyr100 at the catalytic subsite -1 and that this effect is likely a result of cooperation between Tyr100 and Phe259 through stacking interaction with substrate at subsite +2.

Published

2003

37. A synergistic reaction mechanism of a cycloalternan-forming enzyme and a D-glucosyltransferase for the production of cycloalternan in Bacillus sp. NRRL B-21195.

Author

Kim YK, Kitaoka M, Hayashi K, Kim CH, and Côté GL

Subjects

Carbohydrate Sequence, Catalysis, Cyclization, Glucosyltransferases chemistry, Glucosyltransferases isolation & purification, Glycogen Debranching Enzyme System chemistry, Glycogen Debranching Enzyme System isolation & purification, Glycoside Hydrolases chemistry, Glycoside Hydrolases isolation & purification, Molecular Sequence Data, Oligosaccharides chemistry, Polysaccharides metabolism, Starch metabolism, Bacillus enzymology, Glucosyltransferases metabolism, Glycogen Debranching Enzyme System metabolism, Glycoside Hydrolases metabolism, Oligosaccharides metabolism

Abstract

Cycloalternan-forming enzyme (CAFE) was first described as the enzyme that produced cycloalternan from alternan. In this study, we found that a partially purified preparation of CAFE containing two proteins catalyzed the synthesis of cycloalternan from maltooligosaccharides, whereas the purified CAFE alone was unable to do so. In addition to the 117 kDa CAFE itself, the mixture also contained a 140 kDa protein. The latter was found to be a disproportionating enzyme (DE) that catalyzes transfer of a D-glucopyranosyl residue from the non-reducing end of one maltooligosaccharide to the non-reducing end of another, forming an isomaltosyl residue at the non-reducing end. CAFE then transfers the isomaltosyl residue to the non-reducing end of another isomaltosyl maltooligosaccharide, to form an alpha-isomaltosyl-(1-->3)-alpha-isomaltosyl-(1-->4)-maltooligosaccharide, and subsequently catalyzes a cyclization to produce cycloalternan. Thus, DE and CAFE act synergistically to produce cycloalternan directly from maltodextrin or starch.

Published

2003

38. Endoplasmic reticulum-associated degradation of mammalian glycoproteins involves sugar chain trimming to Man6-5GlcNAc2.

Author

Frenkel Z, Gregory W, Kornfeld S, and Lederkremer GZ

Subjects

3T3 Cells, Animals, COS Cells, Calnexin chemistry, Cysteine Endopeptidases metabolism, Down-Regulation, Electrophoresis, Polyacrylamide Gel, Glucose chemistry, Glucosyltransferases chemistry, Glycoproteins chemistry, Glycosylation, Mice, Microscopy, Fluorescence, Models, Biological, Models, Chemical, Multienzyme Complexes metabolism, Mutation, Precipitin Tests, Proteasome Endopeptidase Complex, Protein Folding, Protein Structure, Tertiary, Time Factors, Endoplasmic Reticulum metabolism, Glycoproteins metabolism, Mannose chemistry, Oligosaccharides chemistry

Abstract

Endoplasmic reticulum-associated degradation of misfolded or misprocessed glycoproteins in mammalian cells is prevented by inhibitors of class I alpha-mannosidases implicating mannose trimming from the precursor oligosaccharide Glc3Man9GlcNAc2 as an essential step in this pathway. However, the extent of mannose removal has not been determined. We show here that glycoproteins subject to endoplasmic reticulum-associated degradation undergo reglucosylation, deglucosylation, and mannose trimming to yield Man6GlcNAc2 and Man5GlcNAc2. These structures lack the mannose residue that is the acceptor of glucose transferred by UDP-Glc:glycoprotein glucosyltransferase. This could serve as a mechanism for removal of the glycoproteins from folding attempts catalyzed by cycles of reglucosylation and calnexin/calreticulin binding and result in targeting of these molecules for proteasomal degradation.

Published

2003

39. Cloning and expression of sucrose phosphorylase gene from Bifidobacterium longum in E. coli and characterization of the recombinant enzyme.

Author

Kim M, Kwon T, Lee HJ, Kim KH, Chung DK, Ji GE, Byeon ES, and Lee JH

Subjects

Amino Acid Sequence, Bifidobacterium chemistry, Cloning, Molecular, Enzyme Activation, Escherichia coli chemistry, Gene Expression Regulation, Bacterial physiology, Gene Expression Regulation, Enzymologic physiology, Glucosyltransferases genetics, Molecular Sequence Data, Oligosaccharides classification, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Substrate Specificity, Bifidobacterium enzymology, Bifidobacterium genetics, Escherichia coli enzymology, Escherichia coli genetics, Glucosyltransferases biosynthesis, Glucosyltransferases chemistry, Oligosaccharides chemistry, Protein Engineering methods

Abstract

A DNA fragment, which complemented the growth of E. coli both on M9 medium containing raffinose and on LB medium containing ampicillin, IPTG and 5-bromo-4-chloro-3-indoxyl-alpha-D-galactoside, was isolated from the genomic library of Bifidobacterium longum SJ32, which had been digested with EcoRI. In the cloned DNA fragment, a gene encoding a sucrose phosphorylase (splP) and a partially cloned putative sucrose regulator gene (splR) were identified using the deletion analysis and sequence analysis. A 56 kDa protein was synthesized in E. coli and partially purified by DEAE-ion exchange chromatography. The partially purified enzyme did not react with melibiose, melezitoze and raffinose but did with sucrose. It had transglucosylation activity in addition to hydrolytic activity.

Published

2003

40. Transglycosylation of glycosyl residues to cyclic tetrasaccharide by Bacillus stearothermophilus cyclomaltodextrin glucanotransferase using cyclomaltodextrin as the glycosyl donor.

Author

Shibuya T, Aga H, Watanabe H, Sonoda T, Kubota M, Fukuda S, Kurimoto M, and Tsujisaka Y

Subjects

Aspergillus niger enzymology, Bacillus enzymology, Catalysis, Chromatography, High Pressure Liquid, Glucan 1,4-alpha-Glucosidase metabolism, Glycosylation, Hydrolysis, Mass Spectrometry, Methylation, alpha-Glucosidases metabolism, beta-Amylase metabolism, Geobacillus stearothermophilus enzymology, Glucosyltransferases chemistry, Glycosides chemistry, Oligosaccharides chemistry, Polysaccharides chemistry

Abstract

Cyclomaltodextrin glucanotransferase (EC 2.4.1.19, abbreviated as CGTase) derived from Bacillus stearothermophilus produced a series of transfer products from a mixture of cyclomaltohexaose and cyclic tetrasaccharide (cyclo[-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->], CTS). Of the transfer products, only two components, saccharides A and D, remained and accumulated after digestion with glucoamylase. The total combined yield of the saccharides reached 63.4% of total sugars, and enzymatic and instrumental analyses revealed the structures of both saccharides. Saccharide A was identified as 4-mono-O-alpha-glucosyl-CTS, [-->6)-[alpha-D-Glcp-(1-->4)]-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->], and sachharide D was 4,4'-di-O-alpha-glucosyl-CTS, [-->6)-[alpha-D-Glcp-(1-->4)]-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->6)-[alpha-D-Glcp-(1-->4)]-alpha-D-Glcp-(1-->3)-alpha-D-Glcp-(1-->]. These structures led us to conclude that the glycosyltransfer catalyzed by CGTase was specific to the C4-OH of the 6-linked glucopyranosyl residues in CTS.

Published

2003

41. Oligosaccharide and sucrose complexes of amylosucrase. Structural implications for the polymerase activity.

Author

Skov LK, Mirza O, Sprogøe D, Dar I, Remaud-Simeon M, Albenne C, Monsan P, and Gajhede M

Subjects

Binding Sites, Crystallography, X-Ray, Electrons, Glucans chemistry, Glucosyltransferases metabolism, Models, Chemical, Models, Molecular, Mutation, Neisseria enzymology, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Sucrose chemistry, Glucosyltransferases chemistry, Oligosaccharides chemistry

Abstract

The glucosyltransferase amylosucrase is structurally quite similar to the hydrolase alpha-amylase. How this switch in functionality is achieved is an important and fundamental question. The inactive E328Q amylosucrase variant has been co-crystallized with maltoheptaose, and the structure was determined by x-ray crystallography to 2.2 A resolution, revealing a maltoheptaose binding site in the B'-domain somewhat distant from the active site. Additional soaking of these crystals with maltoheptaose resulted in replacement of Tris in the active site with maltoheptaose, allowing the mapping of the -1 to +5 binding subsites. Crystals of amylosucrase were soaked with sucrose at different concentrations. The structures at approximately 2.1 A resolution revealed three new binding sites of different affinity. The highest affinity binding site is close to the active site but is not in the previously identified substrate access channel. Allosteric regulation seems necessary to facilitate access from this binding site. The structures show the pivotal role of the B'-domain in the transferase reaction. Based on these observations, an extension of the hydrolase reaction mechanism valid for this enzyme can be proposed. In this mechanism, the glycogen-like polymer is bound in the widest access channel to the active site. The polymer binding introduces structural changes that allow sucrose to migrate from its binding site into the active site and displace the polymer.

Published

2002

42. Oligosaccharide synthesis by dextransucrase: new unconventional acceptors.

Author

Demuth K, Jördening HJ, and Buchholz K

Subjects

Carbohydrate Sequence, Kinetics, Molecular Sequence Data, Oligosaccharides chemistry, Stereoisomerism, Substrate Specificity, Glucosyltransferases chemistry, Glucosyltransferases metabolism, Oligosaccharides chemical synthesis, Oligosaccharides metabolism

Abstract

The acceptor reactions of dextransucrase offer the potential for a targeted synthesis of a wide range of di-, tri- and higher oligosaccharides by the transfer of a glucosyl group from sucrose to the acceptor. We here report on results which show that the synthetic potential of this enzyme is not restricted to 'normal' saccharides. Additionally functionalized saccharides, such as alditols, aldosuloses, sugar acids, alkyl saccharides, and glycals, and rather unconventional saccharides, such as fructose dianhydride, may also act as acceptors. Some of these acceptors even turned out to be relatively efficient: alpha-D-glucopyranosyl-(1-->5)-D-arabinonic acid, alpha-D-glucopyranosyl-(1-->4)-D-glucitol, alpha-D-glucopyranosyl-(1-->6)-D-glucitol, alpha-D-glucopyranosyl-(1-->6)-D-mannitol, alpha-D-fructofuranosyl-beta-D-fructofuranosyl-(1,2':2,3')-dianhydride, 1,5-anhydro-2-deoxy-D-arabino-hex-1-enitol ('D-glucal'), and may therefore be of interest for future applications of the dextransucrase acceptor reaction.

Published

2002

43. Molecular characterization of DSR-E, an alpha-1,2 linkage-synthesizing dextransucrase with two catalytic domains.

Author

Bozonnet S, Dols-Laffargue M, Fabre E, Pizzut S, Remaud-Simeon M, Monsan P, and Willemot RM

Subjects

Amino Acid Sequence, Cloning, Molecular, Dextrans metabolism, Glucosyltransferases chemistry, Leuconostoc genetics, Molecular Sequence Data, Oligosaccharides metabolism, Sequence Alignment, Sequence Analysis, DNA, Catalytic Domain genetics, Dextrans chemistry, Glucosyltransferases genetics, Glucosyltransferases metabolism, Leuconostoc enzymology, Oligosaccharides chemistry

Abstract

A novel Leuconostoc mesenteroides NRRL B-1299 dextransucrase gene, dsrE, was isolated, sequenced, and cloned in Escherichia coli, and the recombinant enzyme was shown to be an original glucansucrase which catalyses the synthesis of alpha-1,6 and alpha-1,2 linkages. The nucleotide sequence of the dsrE gene consists of an open reading frame of 8,508 bp coding for a 2,835-amino-acid protein with a molecular mass of 313,267 Da. This is twice the average mass of the glucosyltransferases (GTFs) known so far, which is consistent with the presence of an additional catalytic domain located at the carboxy terminus of the protein and of a central glucan-binding domain, which is also significantly longer than in other glucansucrases. From sequence comparison with family 70 and alpha-amylase enzymes, crucial amino acids involved in the catalytic mechanism were identified, and several original sequences located at some highly conserved regions in GTFs were observed in the second catalytic domain.

Published

2002

44. Maltooligosaccharide disproportionation reaction: an intrinsic property of amylosucrase from Neisseria polysaccharea.

Author

Albenne C, Skov LK, Mirza O, Gajhede M, Potocki-Véronèse G, Monsan P, and Remaud-Simeon M

Subjects

Carbohydrate Conformation, Glucosyltransferases chemistry, Glycosylation, Kinetics, Maltose analogs & derivatives, Maltose chemistry, Maltose metabolism, Oligosaccharides chemistry, Substrate Specificity, Sucrose chemistry, Trisaccharides chemistry, Trisaccharides metabolism, Glucosyltransferases metabolism, Neisseria metabolism, Oligosaccharides metabolism

Abstract

Amylosucrase from Neisseria polysaccharea (AS) is a remarkable transglycosidase of family 13 of the glycoside hydrolases that catalyses the synthesis of an amylose-like polymer from sucrose and is always described as a sucrose-specific enzyme. Here, we demonstrate for the first time the ability of pure AS to catalyse the disproportionation of maltooligosaccharides by cleaving the alpha-1,4 linkage at the non-reducing end of a maltooligosaccharide donor and transferring the glucosyl unit to the non-reducing end of another maltooligosaccharide acceptor. Surprisingly, maltose, maltotriose and maltotetraose are very poor glucosyl donors whereas longer maltooligosaccharides are even more efficient glucosyl donors than sucrose. At least five glucose units are required for efficient transglucosylation, suggesting the existence of strong binding subsites, far from the sucrose binding site, at position +4 and above.

Published

2002

45. Purification and characterization of glucosyltransferase and glucanotransferase involved in the production of cyclic tetrasaccharide in Bacillus globisporus C11.

Author

Nishimoto T, Aga H, Mukai K, Hashimoto T, Watanabe H, Kubota M, Fukuda S, Kurimoto M, and Tsujisaka Y

Subjects

Bacillus metabolism, Chromatography, High Pressure Liquid, Culture Media, Enzyme Stability, Glucans metabolism, Glucosyltransferases chemistry, Hydrogen-Ion Concentration, Kinetics, Magnetic Resonance Spectroscopy, Maltose metabolism, Oligosaccharides chemistry, Soil Microbiology, Substrate Specificity, Temperature, Bacillus enzymology, Glucosyltransferases isolation & purification, Glucosyltransferases metabolism, Oligosaccharides biosynthesis

Abstract

Glucosyltransferase and glucanotransferase involved in the production of cyclic tetrasaccharide (CTS; cyclo [-->6]-alpha-D-glucopyranosyl-(1-->3)-alpha-D-glucopyranosyl-(1-->6)-alpha-D-glucopyranosyl-(1-->3)-alpha-D-glucopyranosyl-(1-->)) from alpha-1,4-glucan were purified from Bacillus globisporus C11. The former was a 1,6-alpha-glucosyltransferase (6GT) catalyzing the a-1,6-transglucosylation of one glucosyl residue to the nonreducing end of maltooligosaccharides (MOS) to produce alpha-isomaltosyl-MOS from MOS. The latter was an isomaltosyl transferase (IMT) catalyzing alpha-1,3-, alpha-1,4-, and alpha,beta-1,1-intermolecular transglycosylation of isomaltosyl residues. When IMT catalyzed alpha-1,3-transglycosylation, alpha-isomaltosyl-(1-->3)-alpha-isomaltosyl-MOS was produced from alpha-isomaltosyl-MOS. In addition, IMT catalyzed cyclization, and produced CTS from alpha-isomaltosyl-(1-->3)-alpha-isomaltosyl-MOS by intramolecular transglycosylation. Therefore, the mechanism of CTS synthesis from MOS by the two enzymes seemed to follow three steps: 1) MOS-->alpha-isomaltosyl-->MOS (by 6GT), 2) alpha-isomaltosyl-MOS-->alpha-isomaltosyl-(1-->3)-alpha-isomaltosyl-MOS (by IMT), and 3) alpha-isomaltosyl-(1-->3)-alpha-isomaltosyl-MOS-->CTS + MOS (by IMT). The molecular mass of 6GT was estimated to be 137 kDa by SDS-PAGE. The optimum pH and temperature for 6GT were pH 6.0 and 45 degrees C, respectively. This enzyme was stable at from pH 5.5 to 10 and on being heated to 40 degrees C for 60 min. 6GT was strongly activated and stabilized by various divalent cations. The molecular mass of IMT was estimated to be 102 kDa by SDS-PAGE. The optimum pH and temperature for IMT were pH 6.0 and 50 degrees C, respectively. This enzyme was stable at from pH 4.5 to 9.0 and on being heated to 40 degrees C for 60 min. Divalent cations had no effect on the stability or activity of this enzyme.

Published

2002

46. Polymerization of glucans by enzymatically active membranes.

Author

Becker M, Provart N, Lehmann I, Ulbricht M, and Hicke HG

Subjects

Bioreactors, Enzyme Activation, Enzymes, Immobilized chemistry, Glucosyltransferases metabolism, Neisseria enzymology, Polymers chemical synthesis, Sensitivity and Specificity, Substrate Specificity, Glucans chemical synthesis, Glucosyltransferases chemistry, Membranes, Artificial, Oligosaccharides chemistry, Polypropylenes, Sucrose chemistry

Abstract

Conventional enzyme membrane reactors are not appropriate for a continuous synthesis of macromolecules and simultaneous product release. By immobilizing the enzyme in sufficiently large pores of a membrane an ensemble of miniaturized bioreactors is created. Product molecules are continuously removed from the enzyme by the flow of the reaction mixture across the membrane. Additionally, by varying the flow rate, it ought to be possible to influence the substrate as well as the enzyme-product residence times and thereby the product macromolecule's size. In this paper we present the first results of experiments involving enzymatic 1,4-alpha-glucan synthesis, using sucrose as substrate, maltooligosaccharides (DP 3-6) as primers, and membrane-immobilized amylosucrase. Epoxy groups for a covalent enzyme immobilization were generated on polypropylene microfiltration membranes by heterogeneous photoinitiated graft polymerization of glycidyl methacrylate. The influence of primer concentration and flow rate through the enzyme-membrane on amylosucrase activity, molecule growth, and coupling efficiency for glucose (% of coupled glucose versus free glucose) were investigated. The enzymatically mediated chain elongation of maltooligosaccharides by the successive addition of glucose units was achieved for the first time in a transmembrane process utilizing amylosucrase membranes.

Published

2002

47. Cloning and sequencing of the genes encoding cyclic tetrasaccharide-synthesizing enzymes from Bacillus globisporus C11.

Author

Aga H, Maruta K, Yamamoto T, Kubota M, Fukuda S, Kurimoto M, and Tsujisaka Y

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, DNA, Bacterial, Glucosyltransferases chemistry, Molecular Sequence Data, Open Reading Frames, Polymerase Chain Reaction, Sequence Homology, Amino Acid, Bacillus enzymology, Glucosyltransferases genetics, Oligosaccharides biosynthesis

Abstract

The genes for isomaltosyltransferase (CtsY) and 6-glucosyltransferase (CtsZ), involved in synthesis of a cyclic tetrasaccharide from alpha-glucan, have been cloned from the genome of Bacillus globisporus C11. The amino-acid sequence deduced from the ctsY gene is composed of 1093 residues having a signal sequence of 29 residues in its N-terminus. The ctsZ gene encodes a protein consisting of 1284 residues with a signal sequence of 35 residues. Both of the gene products show similarities to alpha-glucosidases belonging to glycoside hydrolase family 31 and conserve two aspartic acids corresponding to the putative catalytic residues of these enzymes. The two genes are linked together, forming ctsYZ. The DNA sequence of 16,515 bp analyzed in this study contains four open reading frames (ORFs) upstream of ctsYZ and one ORF downstream. The first six ORFs, including ctsYZ, form a gene cluster, ctsUVWXYZ. The amino-acid sequences deduced from ctsUV are similar in to a sequence permease and a sugar-binding protein for the sugar transport system from Thermococcus sp. B1001. The third ctsW encodes a protein similar to CtsY, suggested to be another isomaltosyltransferase preferring panose to high-molecular-mass substrates.

Published

2002

48. Factors affecting alpha,-1,2 glucooligosaccharide synthesis by Leuconostoc mesenteroides NRRL B-1299 dextransucrase.

Author

Dols-Lafargue M, Willemot RM, Monsan PF, and Remaud-Simeon M

Subjects

Chromatography, High Pressure Liquid, Dextrans chemistry, Disaccharides chemistry, Models, Chemical, Models, Statistical, Sensitivity and Specificity, Glucose chemistry, Glucose metabolism, Glucosyltransferases biosynthesis, Glucosyltransferases chemistry, Leuconostoc enzymology, Oligosaccharides biosynthesis, Oligosaccharides chemistry

Abstract

The optimization of alpha-1,2 glucooligosaccharide (GOS) synthesis from maltose and sucrose by Leuconostoc mesenteroides NRRL B-1299 dextransucrase was achieved using experimental design and consecutive analysis of the key parameters. An increase of the pH of the reaction from 5.4 to 6.7 and of the temperature from 25 to 40 degrees C significantly favored alpha-1,2 GOS synthesis, thanks to a significant decrease of the side reactions, i.e., dextran and leucrose synthesis. These positive effects were not sufficient to compensate for the decrease of enzyme stability caused by the use of high pH and temperature. However, the critical parameters were the sucrose to maltose concentration ratio (S/M) and the total sugar concentration (TSC). Alpha1,2 GOS synthesis was favored at high S/M ratios. But using these conditions also led to an increase of side reactions which could be modulated by choosing the appropriate TSC. Finally, with S/M = 4 and TSC = 45% w/v, dextran and leucrose productions were limited and the final alpha-1,2 GOS yield reached 56.7%, the total GOS yield being 88%., (Copyright 2001 John Wiley & Sons, Inc.)

Published

2001

49. Enzymatic circularization of a malto-octaose linear chain studied by stochastic reaction path calculations on cyclodextrin glycosyltransferase.

Author

Uitdehaag JC, van der Veen BA, Dijkhuizen L, Elber R, and Dijkstra BW

Subjects

Bacillus enzymology, Carbohydrate Sequence, Molecular Sequence Data, Glucosyltransferases chemistry, Oligosaccharides chemistry, Stochastic Processes

Abstract

Cyclodextrin glycosyltransferase (CGTase) is an enzyme belonging to the alpha-amylase family that forms cyclodextrins (circularly linked oligosaccharides) from starch. X-ray work has indicated that this cyclization reaction of CGTase involves a 23-A movement of the nonreducing end of a linear malto-oligosaccharide from a remote binding position into the enzyme acceptor site. We have studied the dynamics of this sugar chain circularization through reaction path calculations. We used the new method of the stochastic path, which is based on path integral theory, to compute an approximate molecular dynamics trajectory of the large (75-kDa) CGTase from Bacillus circulans strain 251 on a millisecond time scale. The result was checked for consistency with site-directed mutagenesis data. The combined data show how aromatic residues and a hydrophobic cavity at the surface of CGTase actively catalyze the sugar chain movement. Therefore, by using approximate trajectories, reaction path calculations can give a unique insight into the dynamics of complex enzyme reactions., (Copyright 2001 Wiley-Liss, Inc.)

Published

2001

50. Structures of Thermoactinomyces vulgaris R-47 alpha-amylase II complexed with substrate analogues.

Author

Yokota T, Tonozuka T, Shimura Y, Ichikawa K, Kamitori S, and Sakano Y

Subjects

Glucosyltransferases chemistry, Micromonosporaceae enzymology, Models, Molecular, Protein Structure, Tertiary, Substrate Specificity, alpha-Amylases physiology, Cyclodextrins chemistry, Oligosaccharides chemistry, alpha-Amylases chemistry, beta-Cyclodextrins

Abstract

The structures of Thermoactinomyces vulgaris R-47 alpha-amylase II mutant (d325nTVA II) complexed with substrate analogues, methyl beta-cyclodextrin (m beta-CD) and maltohexaose (G6), were solved by X-ray diffraction at 3.2 A and 3.3 A resolution, respectively. In d325nTVA II-m beta-CD complex, the orientation and binding-position of beta-CD in TVA II were identical to those in cyclodextin glucanotransferase (CGTase). The active site residues were essentialy conserved, while there are no residues corresponding to Tyr89, Phe183, and His233 of CGTase in TVA II. In d325nTVA II-G6 complex, the electron density maps of two glucosyl units at the non-reducing end were disordered and invisible. The four glucosyl units of G6 were bound to TVA II as in CGTase, while the others were not stacked and were probably flexible. The residues of TVA II corresponding to Tyr89, Lys232, and His233 of CGTase were completely lacking. These results suggest that the lack of the residues related to alpha-glucan and CD-stacking causes the functional distinctions between CGTase and TVA II.

Published

2001