Your search keyword '"Wataru Saburi"' showing total 122 results

1. Discovery of solabiose phosphorylase and its application for enzymatic synthesis of solabiose from sucrose and lactose

Author

Wataru Saburi, Takanori Nihira, Hiroyuki Nakai, Motomitsu Kitaoka, and Haruhide Mori

Subjects

Medicine, Science

Abstract

Abstract Glycoside phosphorylases (GPs), which catalyze the reversible phosphorolysis of glycosides, are promising enzymes for the efficient production of glycosides. Various GPs with new catalytic activities are discovered from uncharacterized proteins phylogenetically distant from known enzymes in the past decade. In this study, we characterized Paenibacillus borealis PBOR_28850 protein, belonging to glycoside hydrolase family 94. Screening of acceptor substrates for reverse phosphorolysis, in which α-d-glucose 1-phosphate was used as the donor substrate, revealed that the recombinant PBOR_28850 produced in Escherichia coli specifically utilized d-galactose as an acceptor and produced solabiose (β-d-Glcp-(1 → 3)-d-Gal). This indicates that PBOR_28850 is a new GP, solabiose phosphorylase. PBOR_28850 catalyzed the phosphorolysis and synthesis of solabiose through a sequential bi-bi mechanism involving the formation of a ternary complex. The production of solabiose from lactose and sucrose has been established. Lactose was hydrolyzed to d-galactose and d-glucose by β-galactosidase. Phosphorolysis of sucrose and synthesis of solabiose were then coupled by adding sucrose, sucrose phosphorylase, and PBOR_28850 to the reaction mixture. Using 210 mmol lactose and 280 mmol sucrose, 207 mmol of solabiose was produced. Yeast treatment degraded the remaining monosaccharides and sucrose without reducing solabiose. Solabiose with a purity of 93.7% was obtained without any chromatographic procedures.

Published

2022

2. Alteration of Substrate Specificity and Transglucosylation Activity of GH13_31 α-Glucosidase from Bacillus sp. AHU2216 through Site-Directed Mutagenesis of Asn258 on β→α Loop 5

Author

Waraporn Auiewiriyanukul, Wataru Saburi, Tomoya Ota, Jian Yu, Koji Kato, Min Yao, and Haruhide Mori

Subjects

α-glucosidase, glycoside hydrolase family 13, transglycosylation, substrate specificity, site-directed mutagenesis, X-ray crystallography, Organic chemistry, QD241-441

Abstract

α-Glucosidase catalyzes the hydrolysis of α-d-glucosides and transglucosylation. Bacillus sp. AHU2216 α-glucosidase (BspAG13_31A), belonging to the glycoside hydrolase family 13 subfamily 31, specifically cleaves α-(1→4)-glucosidic linkages and shows high disaccharide specificity. We showed previously that the maltose moiety of maltotriose (G3) and maltotetraose (G4), covering subsites +1 and +2 of BspAG13_31A, adopts a less stable conformation than the global minimum energy conformation. This unstable d-glucosyl conformation likely arises from steric hindrance by Asn258 on β→α loop 5 of the catalytic (β/α)8-barrel. In this study, Asn258 mutants of BspAG13_31A were enzymatically and structurally analyzed. N258G/P mutations significantly enhanced trisaccharide specificity. The N258P mutation also enhanced the activity toward sucrose and produced erlose from sucrose through transglucosylation. N258G showed a higher specificity to transglucosylation with p-nitrophenyl α-d-glucopyranoside and maltose than the wild type. E256Q/N258G and E258Q/N258P structures in complex with G3 revealed that the maltose moiety of G3 bound at subsites +1 and +2 adopted a relaxed conformation, whereas a less stable conformation was taken in E256Q. This structural difference suggests that stabilizing the G3 conformation enhances trisaccharide specificity. The E256Q/N258G-G3 complex formed an additional hydrogen bond between Met229 and the d-glucose residue of G3 in subsite +2, and this interaction may enhance transglucosylation.

Published

2023

3. Characterization of Antioxidant Activity of Heated Mycosporine-like Amino Acids from Red Alga Dulse Palmaria palmata in Japan

Author

Yuki Nishida, Wataru Saburi, Yoshikatsu Miyabe, Hideki Kishimura, and Yuya Kumagai

Subjects

red alga dulse, mycosporine-like amino acids, palythine, antioxidant activity, Biology (General), QH301-705.5

Abstract

We recently demonstrated the monthly variation and antioxidant activity of mycosporine-like amino acids (MAAs) from red alga dulse in Japan. The antioxidant activity of MAAs in acidic conditions was low compared to that in neutral and alkali conditions, but we found strong antioxidant activity from the heated crude MAA fraction in acidic conditions. In this study, we identified and characterized the key compounds involved in the antioxidant activity of this fraction. We first isolated two MAAs, palythine, and porphyra-334, from the fraction and evaluated the activities of the two MAAs when heated. MAAs possess absorption maxima at around 330 nm, while the heated MAAs lost this absorption. The heated MAAs showed a high ABTS radical scavenging activity at pH 5.8–8.0. We then determined the structure of heated palythine via ESI-MS and NMR analyses and speculated about the putative antioxidant mechanism. Finally, a suitable production condition of the heated compounds was determined at 120 °C for 30 min at pH 8.0. We revealed compounds from red algae with antioxidant activities at a wide range of pH values, and this information will be useful for the functional processing of food.

Published

2022

4. A Ubiquitously Expressed UDP-Glucosyltransferase, UGT74J1, Controls Basal Salicylic Acid Levels in Rice

Author

Daisuke Tezuka, Hideyuki Matsuura, Wataru Saburi, Haruhide Mori, and Ryozo Imai

Subjects

salicylic acid, glycosylation, UDP-glucosyltransferase, disease resistance, Pyricularia oryzae, Botany, QK1-989

Abstract

Salicylic acid (SA) is a phytohormone that regulates a variety of physiological and developmental processes, including disease resistance. SA is a key signaling component in the immune response of many plant species. However, the mechanism underlying SA-mediated immunity is obscure in rice (Oryza sativa). Prior analysis revealed a correlation between basal SA level and blast resistance in a range of rice varieties. This suggested that resistance might be improved by increasing basal SA level. Here, we identified a novel UDP-glucosyltransferase gene, UGT74J1, which is expressed ubiquitously throughout plant development. Mutants of UGT74J1 generated by genome editing accumulated high levels of SA under non-stressed conditions, indicating that UGT74J1 is a key enzyme for SA homeostasis in rice. Microarray analysis revealed that the ugt74j1 mutants constitutively overexpressed a set of pathogenesis-related (PR) genes. An inoculation assay demonstrated that these mutants had increased resistance against rice blast, but they also exhibited stunted growth phenotypes. To our knowledge, this is the first report of a rice mutant displaying SA overaccumulation.

Published

2021

5. Elucidation of the biosynthetic pathway of cis-jasmone in Lasiodiplodia theobromae

Author

Ryo Matsui, Naruki Amano, Kosaku Takahashi, Yodai Taguchi, Wataru Saburi, Hideharu Mori, Norio Kondo, Kazuhiko Matsuda, and Hideyuki Matsuura

Subjects

Medicine, Science

Abstract

Abstract In plants, cis-jasmone (CJ) is synthesized from α-linolenic acid (LA) via two biosynthetic pathways using jasmonic acid (JA) and iso-12-oxo-phytodienoic acid (iso-OPDA) as key intermediates. However, there have been no reports documenting CJ production by microorganisms. In the present study, the production of fungal-derived CJ by Lasiodiplodia theobromae was observed for the first time, although this production was not observed for Botrytis cinerea, Verticillium longisporum, Fusarium oxysporum, Gibberella fujikuroi, and Cochliobolus heterostrophus. To investigate the biosynthetic pathway of CJ in L. theobromae, administration experiments using [18,18,18-2H3, 17,17-2H2]LA (LA-d5), [18,18,18-2H3, 17,17-2H2]12-oxo-phytodienoic acid (cis-OPDA-d5), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 8:0 (OPC8-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 6:0 (OPC6-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 4:0 (OPC4-d6), and [11,11-2H2, 10,10-2H2, 8,8-2H2, 2,2-2H2]methyl iso-12-oxo-phytodienoate (iso-MeOPDA-d8) were carried out, revealing that the fungus produced CJ through a single biosynthetic pathway via iso-OPDA. Interestingly, it was suggested that the previously predicted decarboxylation step of 3,7-didehydroJA to afford CJ might not be involved in CJ biosynthesis in L. theobromae.

Published

2017

6. β-(1→4)-Mannobiose Acts as an Immunostimulatory Molecule in Murine Dendritic Cells by Binding the TLR4/MD-2 Complex

Author

Ting-Yu Cheng, Yen-Ju Lin, Wataru Saburi, Stefan Vieths, Stephan Scheurer, Stefan Schülke, and Masako Toda

Subjects

mannobiose, dendritic cells, immunostimulation, Cytology, QH573-671

Abstract

Some β-mannans, including those in coffee bean and soy, contain a mannose backbone with β-(1→4) bonds. Such mannooligosaccharides could have immunological functions involving direct interaction with immune cells, in addition to acting as prebiotics. This study aimed at assessing the immunological function of mannooligosaccharides with β-(1→4) bond, and elucidating their mechanism of action using bone marrow-derived murine dendritic cells (BMDCs). When BMDCs were stimulated with the mannooligosaccharides, only β-Man-(1→4)-Man significantly induced production of cytokines that included IL-6, IL-10, TNF-α, and IFN-β, and enhanced CD4+ T-cell stimulatory capacity. Use of putative receptor inhibitors revealed the binding of β-Man-(1→4)-Man to TLR4/MD2 complex and involvement with the complement C3a receptor (C3aR) for BMDC activation. Interestingly, β-Man-(1→4)-Man prolonged the production of pro-inflammatory cytokines (IL-6 and TNF-α), but not of the IL-10 anti-inflammatory cytokine during extended culture of BMDCs, associated with high glucose consumption. The results suggest that β-Man-(1→4)-Man is an immunostimulatory molecule, and that the promotion of glycolysis could be involved in the production of pro-inflammatory cytokine in β-Man-(1→4)-Man-stimulated BMDCs. This study could contribute to development of immune-boosting functional foods and a novel vaccine adjuvant.

Published

2021

7. Identification and characterization of extracellular GH3 β-glucosidase from the pink snow mold fungus, Microdochium nivale

Author

Tomoya Ota, Wataru Saburi, Linda Elizabeth Jewell, Tom Hsiang, Ryozo Imai, and Haruhide Mori

Subjects

Organic Chemistry, General Medicine, Molecular Biology, Applied Microbiology and Biotechnology, Biochemistry, Analytical Chemistry, Biotechnology

Abstract

Glycoside hydrolase family 3 (GH3) β-glucosidase exists in many filamentous fungi. In phytopathogenic fungi, it is involved in fungal growth and pathogenicity. Microdochium nivale is a severe phytopathogenic fungus of grasses and cereals and is the causal agent of pink snow mold, but its β-glucosidase has not been identified. In this study, a GH3 β-glucosidase of M. nivale (MnBG3A) was identified and characterized. Among various p-nitrophenyl β-glycosides, MnBG3A showed activity on d-glucoside (pNP-Glc) and slight activity on d-xyloside. In the pNP-Glc hydrolysis, substrate inhibition occurred (Kis = 1.6 m m), and d-glucose caused competitive inhibition (Ki = 0.5 m m). MnBG3A acted on β-glucobioses with β1-3, -6, -4, and -2 linkages, in descending order of kcat/Km. In contrast, the regioselectivity for newly formed products was limited to β1-6 linkage. MnBG3A has similar features to those of β-glucosidases from Aspergillus spp., but higher sensitivity to inhibitory effects.

Published

2023

8. Substrate specificity of glycoside hydrolase family 1 β-glucosidase AtBGlu42 from Arabidopsis thaliana and its molecular mechanism

Author

Shu Horikoshi, Wataru Saburi, Jian Yu, Hideyuki Matsuura, James R Ketudat Cairns, Min Yao, and Haruhide Mori

Subjects

beta-Glucosidase, Organic Chemistry, General Medicine, Molecular Biology, Applied Microbiology and Biotechnology, Biochemistry, Analytical Chemistry, Biotechnology

Abstract

Plants possess many glycoside hydrolase family 1 (GH1) β-glucosidases, which physiologically function in cell wall metabolism and activation of bioactive substances, but most remain uncharacterized. One GH1 isoenzyme AtBGlu42 in Arabidopsis thaliana has been identified to hydrolyze scopolin using the gene deficient plants, but no enzymatic properties were obtained. Its sequence similarity to another functionally characterized enzyme Os1BGlu4 in rice suggests that AtBGlu42 also acts on oligosaccharides. Here, we show that the recombinant AtBGlu42 possesses high kcat/Km not only on scopolin, but also on various β-glucosides, cellooligosaccharides, and laminarioligosaccharides. Of the cellooligosaccharides, cellotriose was the most preferred. The crystal structure, determined at 1.7 Å resolution, suggests that Arg342 gives unfavorable binding to cellooligosaccharides at subsite +3. The mutants R342Y and R342A showed the highest preference on cellotetraose or cellopentaose with increased affinities at subsite +3, indicating that the residues at this position have an important role for chain length specificity.

Published

2021

9. Molecular mechanism for endo-type action of glycoside hydrolase family 55 endo-β-1,3-glucanase on β1-3/1-6-glucan.

Author

Tomoya Ota, Wataru Saburi, Takayoshi Tagami, Jian Yu, Shiro Komba, Elizabeth Jewell, Linda, Tom Hsiang, Ryozo Imai, Min Yao, and Haruhide Mori

Subjects

*GLUCOSIDASES, *GLUCANASES, *BETA-glucans, *MOIETIES (Chemistry), *CRYSTAL structure, *FAMILIES

Abstract

The glycoside hydrolase family 55 (GH55) includes inverting exo-β-1,3-glucosidases and endo-β-1,3-glucanases, acting on laminarin, which is a β1-3/1-6-glucan consisting of a β1-3/1-6- linked main chain and β1-6-linked branches. Despite their different modes of action toward laminarin, endo-β-1,3- glucanases share with exo-β-1,3-glucosidases conserved residues that form the dead-end structure of subsite −1. Here, we investigated the mechanism of endo-type action on laminarin by GH55 endo-β-1,3-glucanase MnLam55A, identified from Microdochium nivale. MnLam55A, like other endo-β-1,3-glucanases, degraded internal β-D-glucosidic linkages of laminarin, producing more reducing sugars than the sum of D-glucose and gentiooligosaccharides detected. β1-3-Glucans lacking β1-6-linkages in the main chain were not hydrolyzed. NMR analysis of the initial degradation of laminarin revealed that MnLam55A preferentially cleaved the nonreducing terminal β1-3-linkage of the laminarioligosaccharide moiety at the reducing end side of the main chain β1-6-linkage. MnLam55A liberates D-glucose from laminaritriose and longer laminarioligosaccharides, but kcat/Km values to laminarioligosaccharides (≤4.21 s−1 mM−1 ) were much lower than to laminarin (5920 s−1 mM−1 ). These results indicate that β-glucan binding to the minus subsites of MnLam55A, including exclusive binding of the gentiobiosyl moiety to subsites −1 and −2, is required for high hydrolytic activity. A crystal structure of MnLam55A, determined at 2.4 Å resolution, showed that MnLam55A adopts an overall structure and catalytic site similar to those of exo-β-1,3-glucosidases. However, MnLam55A possesses an extended substrate-binding cleft that is expected to form the minus subsites. Sequence comparison suggested that other endo-type enzymes share the extended cleft. The specific hydrolysis of internal linkages in laminarin is presumably common to GH55 endo-β-1,3-glucanases. [ABSTRACT FROM AUTHOR]

Published

2023

10. Hydrolysis-transglycosylation of sucrose and production of β-(2→1)-fructan by inulosucrase from Neobacillus drentensis 57N.

Author

Yusuke Kido, Wataru Saburi, Taizo Nagura, and Haruhide Mori

Subjects

*INULIN, *HIGH performance liquid chromatography, *POLYSACCHARIDES

Abstract

Inulin, β-(2→1)-fructan, is a beneficial polysaccharide used as a functional food ingredient. Microbial inulosucrases (ISs), catalyzing β-(2→1)-transfructosylation, produce β-(2→1)-fructan from sucrose. In this study, we identified a new IS (NdIS) from the soil isolate, Neobacillus drentensis 57N. Sequence analysis revealed that, like other Bacillaceae ISs, NdIS consists of a glycoside hydrolase family 68 domain and shares most of the 1-kestose-binding residues of the archaeal IS, InuHj. Native and recombinant NdIS were characterized. NdIS is a homotetramer. It does not require calcium for activity. High performance liquid chromatography and 13C-nuclear magnetic resonance indicated that NdIS catalyzed the hydrolysis and β-(2→1)-transfructosylation of sucrose to synthesize β-(2→1)-fructan with chain lengths of 42 or more residues. The rate dependence on sucrose concentration followed hydrolysis–transglycosylation kinetics, and a 50% transglycosylation ratio was obtained at 344 mm sucrose. These results suggest that transfructosylation from sucrose to β-(2→1)-fructan occurs predominantly to elongate the fructan chain because sucrose is an unfavorable acceptor. [ABSTRACT FROM AUTHOR]

Published

2023

11. Chemical synthesis of oligosaccharide derivatives with partial structure of β1-3/1-6 glucan, using monomeric units for the formation of β1-3 and β1-6 glucosidic linkages.

Author

Tomoya Ota, Wataru Saburi, Shiro Komba, and Haruhide Mori

Subjects

*CHEMICAL synthesis, *GLUCANS, *OLIGOSACCHARIDES, *BETA-glucans, *MARINE algae

Abstract

β1-3/1-6 Glucans, known for their diverse structures, comprise a β1-3-linked main chain and β1-6-linked short branches. Laminarin, a β1-3/1-6 glucan extracted from brown seaweed, for instance, includes β1-6 linkages even in the main chain. The diverse structures provide various beneficial functions for the glucan. To investigate the relationship between structure and functionality, and to enable the characterization of β1-3/1-6 glucan-metabolizing enzymes, oligosaccharides containing the exact structures of β1-3/1-6 glucans are required. We synthesized the monomeric units for the synthesis of β1-3/1-6 mixed-linked glucooligosaccharides. 2-(Trimethylsilyl)ethyl 2-O-benzoyl-4,6-O-benzylidene-β-d-glucopyranoside served as an acceptor in the formation of β1-3 linkages. Phenyl 2-O-benzoyl-4,6-O-benzylidene-3-O-(tert-butyldiphenylsilyl)-1-thio-β-d-glucopyranoside and phenyl 2,3-di-O-benzoyl-4,6-di-O-levulinyl-1-thio-β-d-glucopyranoside acted as donors, synthesizing acceptors suitable for the formation of β1-3- and β1-6-linkages, respectively. These were used to synthesize a derivative of Glcβ1-6Glcβ1-3Glcβ1-3Glc, demonstrating that the proposed route can be applied to synthesize the main chain of β-glucan, with the inclusion of both β1-3 and β1-6 linkages. [ABSTRACT FROM AUTHOR]

Published

2023

12. Functional characterization of a novel GH94 glycoside phosphorylase, 3-O-β-d-glucopyranosyl β-d-glucuronide phosphorylase, and implication of the metabolic pathway of acidic carbohydrates in Paenibacillus borealis

Author

Naoto Isono, Emi Mizutani, Haruka Hayashida, Hirotaka Katsuzaki, and Wataru Saburi

Subjects

Glucuronides, Glucuronic Acid, Glycoside Hydrolases, Phosphorylases, Glucosyltransferases, Biophysics, Cell Biology, Glycosides, Molecular Biology, Biochemistry, Paenibacillus, Metabolic Networks and Pathways, Substrate Specificity

Abstract

Glycoside hydrolase family 94 (GH94) contains enzymes that reversibly catalyze the phosphorolysis of β-glycosides. We conducted this study to investigate a GH94 protein (PBOR_13355) encoded in the genome of Paenibacillus borealis DSM 13188 with low sequence identity to known phosphorylases. Screening of acceptor substrates for reverse phosphorolysis in the presence of α-d-glucose 1-phosphate as a donor substrate showed that PBOR_13355 utilized d-glucuronic acid and p-nitrophenyl β-d-glucuronide as acceptors. In the reaction with d-glucuronic acid, 3-O-β-d-glucopyranosyl-d-glucuronic acid was synthesized. PBOR_13355 showed a higher apparent catalytic efficiency to p-nitrophenyl β-d-glucuronide than to d-glucuronic acid, and thus, PBOR_13355 was concluded to be a novel glycoside phosphorylase, 3-O-β-d-glucopyranosyl β-d-glucuronide phosphorylase. PBOR_13360, encoded by the gene immediately downstream of the PBOR_13355 gene, was shown to be β-glucuronidase. Collectively, PBOR_13355 and PBOR_13360 are predicted to work together in the cytosol to metabolize oligosaccharides containing the 3-O-β-d-glucopyranosyl β-d-glucuronide structure released from bacterial and plant acidic carbohydrates.

Published

2022

13. A model system for studying plant–microbe interactions under snow

Author

Tamotsu Hoshino, Chikako Kuwabara, Natsuki Umeki, Kentaro Sasaki, Wataru Saburi, Hirokazu Matsui, and Ryozo Imai

Subjects

0106 biological sciences, 0301 basic medicine, Regular Issue, Physiology, Acclimatization, Arabidopsis, Model system, Plant Science, Biology, Models, Biological, 01 natural sciences, 03 medical and health sciences, Snow, Genetics, Disease Resistance, Plant Diseases, Host Microbial Interactions, Basidiomycota, fungi, food and beverages, Plant microbe, Cold Temperature, 030104 developmental biology, Biochemical engineering, human activities, 010606 plant biology & botany

Abstract

A model plant–pathogen system using Arabidopsis and its natural snow mold pathogen Typhula ishikariensis demonstrated Arabidopsis plants develop disease resistance through cold acclimation.

Published

2021

14. Preliminary evaluation of colorimetric and HPLC-based methods for quantifying β-(1→4)-mannobiose in a crude material

Author

Wataru Saburi, Kensuke Fukui, Kazunobu Tsumura, Haruhide Mori, and Masahisa Ibuki

Subjects

Marketing, Chromatography, Chemistry, General Chemical Engineering, Mannobiose, High-performance liquid chromatography, Industrial and Manufacturing Engineering, Food Science, Biotechnology

Published

2021

15. A practical approach to producing isomaltomegalosaccharide using dextran dextrinase from Gluconobacter oxydans ATCC 11894

Author

Weeranuch Lang, Yuya Kumagai, Juri Sadahiro, Wataru Saburi, Rakrudee Sarnthima, Takayoshi Tagami, Masayuki Okuyama, Haruhide Mori, Nobuo Sakairi, Doman Kim, and Atsuo Kimura

Subjects

Gluconobacter oxydans, Dextran dextrinase, Chimeric glucosaccharide, General Medicine, Dextran, Isomaltomegalosaccharide, Applied Microbiology and Biotechnology, Biotechnology

Abstract

Dextran dextrinase (DDase) catalyzes formation of the polysaccharide dextran from maltodextrin. During the synthesis of dextran, DDase also generates the beneficial material isomaltomegalosaccharide (IMS). The term megalosaccharide is used for a saccharide having DP=10-100 or 10-200 (DP, degree of polymerization). IMS is a chimeric glucosaccharide comprising alpha-(1 -> 6)- and alpha-(1 -> 4)-linked portions at the nonreducing and reducing ends, respectively, in which the alpha-(1 -> 4)-glucosyl portion originates from maltodextrin of the substrate. In this study, IMS was produced by a practical approach using extracellular DDase (DDext) or cell surface DDase (DDsur) of Gluconobacter oxydans ATCC 11894. DDsur was the original form, so we prepared DDext via secretion from intact cells by incubating with 0.5% G6/G7 (maltohexaose/maltoheptaose); this was followed by generation of IMS from various concentrations of G6/G7 substrate at different temperatures for 96 h. However, IMS synthesis by DDext was limited by insufficient formation of alpha-(1 -> 6)-glucosidic linkages, suggesting that DDase also catalyzes elongation of alpha-(1 -> 4)-glucosyl chain. For production of IMS using DDsur, intact cells bearing DDsur were directly incubated with 20% G6/G7 at 45 degrees C by optimizing conditions such as cell concentration and agitation efficiency, which resulted in generation of IMS (average DP =14.7) with 61% alpha-(1 -> 6)-glucosyl content in 51% yield. Increases in substrate concentration and agitation efficiency were found to decrease dextran formation and increase IMS production, which improved the reaction conditions for DDext. Under modified conditions (20% G6/G7, agitation speed of 100 rpm at 45 degrees C), DDext produced IMS (average DP =14.5) with 65% alpha-(1 -> 6)-glucosyl content in a good yield of 87%.

Published

2022

16. Function and Structure of Lacticaseibacillus casei GH35 β-Galactosidase LBCZ_0230 with High Hydrolytic Activity to Lacto-N-biose I and Galacto-N-biose.

Author

Wataru Saburi, Tomoya Ota, Koji Kato, Takayoshi Tagami, Keitaro Yamashita, Min Yao, and Haruhide Mori

Subjects

GALACTOSIDASES, PROBIOTICS, HYDROLYSIS, PROTEINS, AROMATIC compounds

Abstract

ß-Galactosidase (EC 3.2.1.23) hydrolyzes β-D-galactosidic linkages at the non-reducing end of substrates to produce β-D-galactose. Lacticaseibacillus casei is one of the most widely utilized probiotic species of lactobacilli. It possesses a putative β-galactosidase belonging to glycoside hydrolase family 35 (GH35). This enzyme is encoded by the gene included in the gene cluster for utilization of lacto-N-biose I (LNB; Galβ1-3GlcNAc) and galacto-N-biose (GNB; Galβ1-3GalNAc) via the phosphoenolpyruvate: sugar phosphotransferase system. The GH35 protein (GnbG) from L. casei BL23 is predicted to be 6-phospho-β-galactosidase (EC 3.2.1.85). However, its 6-phospho-β-galactosidase activity has not yet been examined, whereas its hydrolytic activity against LNB and GNB has been demonstrated. In this study, L. casei JCM1134 LBCZ_0230, homologous to GnbG, was characterized enzymatically and structurally. A recombinant LBCZ_0230, produced in Escherichia coli, exhibited high hydrolytic activity toward o-nitrophenyl β-D-galactopyranoside, p-nitrophenyl β-D-galactopyranoside, LNB, and GNB, but not toward o-nitrophenyl 6-phospho-β-D-galactopyranoside. Crystal structure analysis indicates that the structure of subsite -1 of LBCZ_0230 is very similar to that of Streptococcus pneumoniae β-galactosidase BgaC and not suitable for binding to 6-phospho-β-D-galactopyranoside. These biochemical and structural analyses indicate that LBCZ_0230 is a β-galactosidase. According to the prediction of LNB's binding mode, aromatic residues, Trp190, Trp240, Trp243, Phe244, and Tyr458, form hydrophobic interactions with N-acetyl-D-glucosamine residue of LNB at subsite +1. [ABSTRACT FROM AUTHOR]

Published

2023

17. Discovery of solabiose phosphorylase and its application for enzymatic synthesis of solabiose from sucrose and lactose

Author

Wataru Saburi, Takanori Nihira, Hiroyuki Nakai, Haruhide Mori, and Motomitsu Kitaoka

Subjects

Sucrose, Phosphorylases, Science, Lactose, Disaccharides, Biochemistry, Microbiology, Catalysis, Article, Substrate Specificity, chemistry.chemical_compound, Glycogen phosphorylase, Bacterial Proteins, Catalytic Domain, Multidisciplinary, Binding Sites, Hydrolysis, Enzymatic synthesis, Kinetics, chemistry, Medicine, Paenibacillus, Biotechnology

Abstract

Glycoside phosphorylases (GPs), which catalyze the reversible phosphorolysis of glycosides, are promising enzymes for the efficient production of glycosides. Various GPs with new catalytic activities are discovered from uncharacterized proteins phylogenetically distant from known enzymes in the past decade. In this study, we characterized Paenibacillus borealis PBOR_28850 protein, belonging to glycoside hydrolase family 94. Screening of acceptor substrates for reverse phosphorolysis, in which α-d-glucose 1-phosphate was used as the donor substrate, revealed that the recombinant PBOR_28850 produced in Escherichia coli specifically utilized d-galactose as an acceptor and produced solabiose (β-d-Glcp-(1 → 3)-d-Gal). This indicates that PBOR_28850 is a new GP, solabiose phosphorylase. PBOR_28850 catalyzed the phosphorolysis and synthesis of solabiose through a sequential bi-bi mechanism involving the formation of a ternary complex. The production of solabiose from lactose and sucrose has been established. Lactose was hydrolyzed to d-galactose and d-glucose by β-galactosidase. Phosphorolysis of sucrose and synthesis of solabiose were then coupled by adding sucrose, sucrose phosphorylase, and PBOR_28850 to the reaction mixture. Using 210 mmol lactose and 280 mmol sucrose, 207 mmol of solabiose was produced. Yeast treatment degraded the remaining monosaccharides and sucrose without reducing solabiose. Solabiose with a purity of 93.7% was obtained without any chromatographic procedures.

Published

2021

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

Author

Wataru Saburi, Haruhide Mori, Yodai Taguchi, and Yu Gao

Subjects

0301 basic medicine, chemistry.chemical_classification, Kojibiose, 030102 biochemistry & molecular biology, Organic Chemistry, General Medicine, Maltose, Applied Microbiology and Biotechnology, Biochemistry, Maltose phosphorylase, Analytical Chemistry, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Enzyme, chemistry, Maltotriose, Glycoside hydrolase, Enzyme kinetics, Molecular Biology, Biotechnology, Phosphorolysis

Abstract

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

Published

2019

19. Enzymatic characteristics of d-mannose 2-epimerase, a new member of the acylglucosamine 2-epimerase superfamily

Author

Wataru Saburi, Saki Hashiguchi, Haruhide Mori, Suzuka Sato, Hirohiko Muto, and Iizuka Takahisa

Subjects

Anomer, Stereochemistry, Cytophagaceae, Mannose, d-mannose, Cellobiose, Isomerase, Applied Microbiology and Biotechnology, Substrate Specificity, d-mannose isomerase, 03 medical and health sciences, chemistry.chemical_compound, Enzyme kinetics, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Acylglucosamine 2-epimerase, 030306 microbiology, Temperature, Substrate (chemistry), General Medicine, Hydrogen-Ion Concentration, Carbohydrate Epimerases, Kinetics, Glucose, Enzyme, Epimerase, chemistry, Cellobiose 2-epimerase, Biotechnology

Abstract

Carbohydrate epimerases and isomerases are essential for the metabolism and synthesis of carbohydrates. In this study, Runella slithyformis Runsl_4512 and Dyadobacter fermentans Dfer_5652 were characterized from a cluster of uncharacterized proteins of the acylglucosamine 2-epimerase (AGE) superfamily. These proteins catalyzed the intramolecular conversion of d-mannose to d-glucose, whereas they did not act on beta-(1 -> 4)-mannobiose, N-acetyl-d-glucosamine, and d-fructose, which are substrates of known AGE superfamily members. The k(cat)/K-m values of Runsl_4512 and Dfer_5652 for d-mannose epimerization were 3.89 and 3.51min(-1)mM(-1), respectively. Monitoring the Runsl_4512 reaction through H-1-NMR showed the formation of beta-d-glucose and beta-d-mannose from d-mannose and d-glucose, respectively. In the reaction with beta-d-glucose, beta-d-mannose was produced at the initial stage of the reaction, but not in the reaction with alpha-d-glucose. These results indicate that Runsl_4512 catalyzed the 2-epimerization of the beta-anomer substrate with a net retention of the anomeric configuration. Since H-2 was obviously detected at the 2-C position of d-mannose and d-glucose in the equilibrated reaction mixture produced by Runsl_4512 in (H2O)-H-2, this enzyme abstracts 2-H from the substrate and adds another proton to the intermediate. This mechanism is in accordance with the mechanism proposed for the reactions of other epimerases of the AGE superfamily, that is, AGE and cellobiose 2-epimerase. Upon reaction with 500g/L d-glucose at 50 degrees C and pH8.0, Runsl_4512 and Dfer_5652 produced d-mannose with a 24.4 and 22.8% yield, respectively. These d-mannose yields are higher than those of other enzyme systems, and ME acts as an efficient biocatalyst for producing d-mannose.

Published

2019

20. Enzymatic production of xylooligosaccharides from red alga dulse (Palmaria sp.) wasted in Japan

Author

Takao Ojima, Hideki Kishimura, Yuya Kumagai, Wataru Saburi, Yasunori Kinoshita, Hajime Yasui, and Yohei Yamamoto

Subjects

chemistry.chemical_classification, Red alga, biology, Bioengineering, Red algae, Xylose, biology.organism_classification, Applied Microbiology and Biotechnology, Biochemistry, Xylan, Hydrolysate, chemistry.chemical_compound, Hydrolysis, Enzyme, Xylooligosaccharides, chemistry, Hemicellulase, Lignin, Food science, Cellulose, Palmaria sp

Abstract

Red alga dulse (Palmaria sp.) has xylan with a small amount of cellulose and less lignin, hence these characteristics may provide some advantages in the enzymatic production of xylooligosaccharides (XOS). To evaluate dulse xylan as XOS source, we prepared xylan rich fraction (DXRF) and attempted XOS production using commercial enzymes. 13.8% of xylan rich fraction (DXRF: containing 52.2% of xylan) was obtained from dried dulse powder. We then evaluated the hydrolysis products of two commercial enzymes, revealing that hydrolysate of Hemicellulase amano 90 contained less xylose. The effective XOS production by the enzyme was evaluated in terms of enzyme dose, DXRF concentration and reaction period, showing that 66.6% of XOS was obtained from DXRF with the hydrolysis rate of 82% under the following condition: 54 U Hemicellulase amano 90, 10 mg/ml DXRF, pH 4.5, 50 °C for 24 h. These results indicated that red algae xylan is suitable for XOS source.

Published

2019

21. A ubiquitously expressed UDP-glucosyltransferase, UGT74J1, controls basal salicylic acid levels in rice

Author

Haruhide Mori, Wataru Saburi, Daisuke Tezuka, Ryozo Imai, and Hideyuki Matsuura

Subjects

chemistry.chemical_classification, Oryza sativa, Microarray analysis techniques, Mutant, food and beverages, Plant disease resistance, Biology, Phenotype, Cell biology, chemistry.chemical_compound, Enzyme, chemistry, Gene, Salicylic acid

Abstract

Salicylic acid (SA) is a phytohormone that regulates a variety of physiological and developmental processes, including disease resistance. SA is a key signaling component in the immune response of many plant species. However, the mechanism underlying SA-mediated immunity is obscure in rice (Oryza sativa). Prior analysis revealed a correlation between basal SA level and blast resistance in a range of rice varieties. This suggested that resistance might be improved by increasing basal SA level. Here, we identified a novel UDP-glucosyltransferase gene, UGT74J1, which is expressed ubiquitously throughout plant development. Mutants of UGT74J1 generated by genome editing accumulated high levels of SA under non-stressed conditions, indicating that UGT74J1 is a key enzyme for SA homeostasis in rice. Microarray analysis revealed that the ugt74j1 mutants constitutively overexpressed a set of pathogenesis-related (PR) genes. An inoculation assay demonstrated that these mutants had increased resistance against rice blast, but they also exhibited stunted growth phenotypes. To our knowledge, this is the first report of a rice mutant displaying SA overaccumulation.

Published

2021

22. Biochemical and structural characterization of Marinomonas mediterranea d-mannose isomerase Marme_2490 phylogenetically distant from known enzymes

Author

Yuka Tanaka, Wataru Saburi, Koji Kato, Haruhide Mori, Nongluck Jaito, and Min Yao

Subjects

0106 biological sciences, 0301 basic medicine, Lyxose, Stereochemistry, Mannose, Cellobiose, Isomerase, Disaccharides, 01 natural sciences, Biochemistry, Substrate Specificity, Evolution, Molecular, 03 medical and health sciences, chemistry.chemical_compound, Isomerism, 010608 biotechnology, Mannose isomerase, Marinomonas, Aldose-Ketose Isomerases, Phylogeny, chemistry.chemical_classification, Temperature, Fructose, Talose, General Medicine, Hydrogen-Ion Concentration, Kinetics, 030104 developmental biology, Enzyme, chemistry

Abstract

d -Mannose isomerase (MI) reversibly isomerizes d -mannose to d -fructose, and is attractive for producing d -mannose from inexpensive d -fructose. It belongs to the N-acylglucosamine 2-epimerase (AGE) superfamily along with AGE, cellobiose 2-epimerase (CE), and aldose-ketose isomerase (AKI). In this study, Marinomonas mediterranea Marme_2490, showing low sequence identity with any known enzymes, was found to isomerize d -mannose as its primary substrate. Marme_2490 also isomerized d -lyxose and 4-OH d -mannose derivatives ( d -talose and 4-O-monosaccharyl- d -mannose). Its activity for d -lyxose is known in other d -mannose isomerizing enzymes, such as MI and AKI, but we identified, for the first time, its activity for 4-OH d -mannose derivatives. Marme_2490 did not isomerize d -glucose, as known MIs do not, while AKI isomerizes both d -mannose and d -glucose. Thus, Marme_2490 was concluded to be an MI. The initial and equilibrium reaction products were analyzed by NMR to illuminate mechanistic information regarding the Marme_2490 reaction. The analysis of the initial reaction product revealed that β- d -mannose was formed. In the analysis of the equilibrated reaction products in D2O, signals of 2-H of d -mannose and 1-H of d -fructose were clearly detected. This indicates that these protons are not substituted with deuterium from D2O and Marme_2490 catalyzes the intramolecular proton transfer between 1-C and 2-C. The crystal structure of Marme_2490 in a ligand-free form was determined and found that Marme_2490 is formed by an (α/α)6-barrel, which is commonly observed in AGE superfamily enzymes. Despite diverse reaction specificities, the orientations of residues involved in catalysis and substrate binding by Marme_2490 were similar to those in both AKI (Salmonella enterica AKI) and epimerase (Rhodothermus marinus CE). The Marme_2490 structure suggested that the α7→α8 and α11→α12 loops of the catalytic domain participated in the formation of an open substrate-binding site to provide sufficient space to bind 4-OH d -mannose derivatives.

Published

2018

23. [Review] Structures and Functions of Cellobiose 2-Epimerase and β-Mannoside Phosphorylases Involved in β-Mannan Degradation

Author

Wataru Saburi, Koji Kato, Min Yao, Hirokazu Matsui, and Haruhide Mori

Subjects

General Medicine

Published

2017

24. Biochemical characteristics of maltose phosphorylase MalE from

Author

Yu, Gao, Wataru, Saburi, Yodai, Taguchi, and Haruhide, Mori

Subjects

Glucosyltransferases, Temperature, Oligosaccharides, Bacillus, Chemistry Techniques, Synthetic, Hydrogen-Ion Concentration, Phosphorylation, Substrate Specificity

Abstract

Maltose phosphorylase (MP), a glycoside hydrolase family 65 enzyme, reversibly phosphorolyzes maltose. In this study, we characterized

Published

2019

25. Substrate specificity of glycoside hydrolase family 1 β-glucosidase AtBGlu42 from Arabidopsis thaliana and its molecular mechanism.

Author

Shu Horikoshi, Wataru Saburi, Jian Yu, Hideyuki Matsuura, Ketudat Cairns, James R., Min Yao, and Haruhide Mori

Subjects

GLUCOSIDASES, ARABIDOPSIS thaliana, CELL metabolism, PLANT genes, CRYSTAL structure, CELL physiology

Abstract

Plants possess many glycoside hydrolase family 1 ( GH1 ) β-glucosidases, which physiologically function in cell wall metabolism and activation of bioactive substances, but most remain uncharacterized. One GH1 isoenzyme AtBGlu42 in Arabidopsis thaliana has been identified to hydrolyze scopolin using the gene deficient plants, but no enzymatic properties were obtained. Its sequence similarity to another functionally characterized enzyme Os1BGlu4 in rice suggests that AtBGlu42 also acts on oligosaccharides. Here, we show that the recombinant AtBGlu42 possesses high k cat / K m not only on scopolin, but also on various β-glucosides, cellooligosaccharides, and laminarioligosaccharides. Of the cellooligosaccharides, cellotriose was the most preferred. The crystal structure, determined at 1.7 Å resolution, suggests that Arg342 gives unfavorable binding to cellooligosaccharides at subsite + 3. The mutants R342Y and R342A showed the highest preference on cellotetraose or cellopentaose with increased affinities at subsite + 3, indicating that the residues at this position have an important role for chain length specificity. [ABSTRACT FROM AUTHOR]

Published

2022

26. α-Glucosidases and α-1,4-glucan lyases: structures, functions, and physiological actions

Author

Wataru Saburi, Haruhide Mori, Masayuki Okuyama, and Atsuo Kimura

Subjects

Models, Molecular, 0301 basic medicine, Sucrose, Glycosylation, Stereochemistry, Mutant, Biology, Substrate Specificity, 03 medical and health sciences, Cellular and Molecular Neuroscience, Hydrolysis, Glycoside hydrolase, Amino Acid Sequence, Lyase activity, Molecular Biology, Polysaccharide-Lyases, Glucan, Pharmacology, chemistry.chemical_classification, Catabolism, α glucosidase, alpha-Glucosidases, Cell Biology, 030104 developmental biology, Enzyme, chemistry, Biochemistry, Molecular Medicine

Abstract

α-Glucosidases (AGases) and α-1,4-glucan lyases (GLases) catalyze the degradation of α-glucosidic linkages at the non-reducing ends of substrates to release α-glucose and anhydrofructose, respectively. The AGases belong to glycoside hydrolase (GH) families 13 and 31, and the GLases belong to GH31 and share the same structural fold with GH31 AGases. GH13 and GH31 AGases show diverse functions upon the hydrolysis of substrates, having linkage specificities and size preferences, as well as upon transglucosylation, forming specific α-glucosidic linkages. The crystal structures of both enzymes were determined using free and ligand-bound forms, which enabled us to understand the important structural elements responsible for the diverse functions. A series of mutational approaches revealed features of the structural elements. In particular, amino-acid residues in plus subsites are of significance, because they regulate transglucosylation, which is used in the production of industrially valuable oligosaccharides. The recently solved three-dimensional structure of GLase from red seaweed revealed the amino-acid residues essential for lyase activity and the strict recognition of the α-(1 → 4)-glucosidic substrate linkage. The former was introduced to the GH31 AGase, and the resultant mutant displayed GLase activity. GH13 and GH31 AGases hydrate anhydrofructose to produce glucose, suggesting that AGases are involved in the catabolic pathway used to salvage unutilized anhydrofructose.

Published

2016

27. Structural insights into the difference in substrate recognition of two mannoside phosphorylases from two GH130 subfamilies

Author

Mamoru Nishimoto, Naofumi Sakurai, Wataru Saburi, Keisuke Komoda, Haruhide Mori, Min Yao, Koji Kato, Motomitsu Kitaoka, Yuxin Ye, and Rei Odaka

Subjects

Models, Molecular, 0301 basic medicine, Glycoside Hydrolases, Phosphorylases, Protein Conformation, Stereochemistry, Static Electricity, Biophysics, Crystallography, X-Ray, Biochemistry, Substrate Specificity, 03 medical and health sciences, Glycogen phosphorylase, Protein structure, Bacterial Proteins, Structural Biology, Catalytic Domain, Ruminococcus, Genetics, Mannobiose, Transferase, Glycoside hydrolase, Protein Structure, Quaternary, Molecular Biology, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, Chemistry, Substrate (chemistry), Cell Biology, biology.organism_classification, 030104 developmental biology, Enzyme, Mannosides

Abstract

In Ruminococcus albus, 4-O-β-D-mannosyl-D-glucose phosphorylase (RaMP1) and β-(1,4)-mannooligosaccharide phosphorylase (RaMP2) belong to two subfamilies of glycoside hydrolase family 130. The two enzymes phosphorolyze β-mannosidic linkages at the nonreducing ends of their substrates, and have substantially diverse substrate specificity. The differences in their mechanism of substrate binding have not yet been fully clarified. In the present study, we report the crystal structures of RaMP1 with/without 4-O-β-D-mannosyl-d-glucose and RaMP2 with/without β-(1→4)-mannobiose. The structures of the two enzymes differ at the +1 subsite of the substrate-binding pocket. Three loops are proposed to determine the different substrate specificities. One of these loops is contributed from the adjacent molecule of the oligomer structure. In RaMP1, His245 of loop 3 forms a hydrogen-bond network with the substrate through a water molecule, and is indispensible for substrate binding.

Published

2016

28. The rice ethylene response factor OsERF83 positively regulates disease resistance to Magnaporthe oryzae

Author

Daisuke Tezuka, Haruhide Mori, Ryozo Imai, Wataru Saburi, Hideki Kato, and Aya Kawamata

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Electrophoretic Mobility Shift Assay, Plant Science, Plant disease resistance, Biology, Real-Time Polymerase Chain Reaction, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Transactivation, Genetics, Transcription factor, Phylogeny, Disease Resistance, Plant Diseases, Plant Proteins, Oryza sativa, Methyl jasmonate, food and beverages, Oryza, Biotic stress, Ethylenes, Plants, Genetically Modified, Genetically modified rice, Recombinant Proteins, Cell biology, Magnaporthe, 030104 developmental biology, chemistry, Trans-Activators, 010606 plant biology & botany, Ethephon

Abstract

Rice blast caused by Magnaporthe oryzae is one of the most destructive diseases of rice (Oryza sativa) worldwide. Here, we report the identification and functional characterization of a novel ethylene response factor (ERF) gene, OsERF83, which was expressed in rice leaves in response to rice blast fungus infection. OsERF83 expression was also induced by treatments with methyl jasmonate, ethephon, and salicylic acid, indicating that multiple phytohormones could be involved in the regulation of OsERF83 expression under biotic stress. Subcellular localization and transactivation analyses demonstrated that OsERF83 is a nucleus-localized transcriptional activator. A gel-shift assay using recombinant OsERF83 protein indicated that, like other ERFs, it binds to the GCC box. Transgenic rice plants overexpressing OsERF83 exhibited significantly suppressed lesion formation after rice blast infection, indicating that OsERF83 positively regulates disease resistance in rice. Genes encoding several classes of pathogenesis-related (PR) proteins, including PR1, PR2, PR3, PR5, and PR10, were upregulated in the OsERF83ox plants. Taken together, our findings show that OsERF83 is a novel ERF transcription factor that confers blast resistance by regulating the expression of defense-related genes in rice.

Published

2018

29. A Transposon Mutagenesis System for Bifidobacterium longum subsp. longum Based on an IS 3 Family Insertion Sequence, IS Blo11

Author

Shingo Nakakawaji, Haruhide Mori, Satoru Fukiya, Wataru Saburi, Arisa Abe, Mikiyasu Sakanaka, Shin Nakajima, and Atsushi Yokota

Subjects

0301 basic medicine, Genetics, Transposable element, Bifidobacterium longum, Ecology, biology, Inverted repeat, 030106 microbiology, biology.organism_classification, Applied Microbiology and Biotechnology, 03 medical and health sciences, fluids and secretions, Plasmid, Transposon mutagenesis, Insertion sequence, Gene, Transposase, Food Science, Biotechnology

Abstract

Bifidobacteria are a major component of the intestinal microbiota in humans, particularly breast-fed infants. Therefore, elucidation of the mechanisms by which these bacteria colonize the intestine is desired. One approach is transposon mutagenesis, a technique currently attracting much attention because, in combination with next-generation sequencing, it enables exhaustive identification of genes that contribute to microbial fitness. We now describe a transposon mutagenesis system for Bifidobacterium longum subsp. longum 105-A (JCM 31944) based on ISBlo11, a native IS3 family insertion sequence. To build this system, xylose-inducible or constitutive bifidobacterial promoters were tested to drive the expression of full-length or a truncated form at the N terminus of the ISBlo11 transposase. An artificial transposon plasmid, pBFS12, in which ISBlo11 terminal inverted repeats are separated by a 3-bp spacer, was also constructed to mimic the transposition intermediate of IS3 elements. The introduction of this plasmid into a strain expressing transposase resulted in the insertion of the plasmid with an efficiency of >103 CFU/μg DNA. The plasmid targets random 3- to 4-bp sequences, but with a preference for noncoding regions. This mutagenesis system also worked at least in B. longum NCC2705. Characterization of a transposon insertion mutant revealed that a putative α-glucosidase mediates palatinose and trehalose assimilation, demonstrating the suitability of transposon mutagenesis for loss-of-function analysis. We anticipate that this approach will accelerate functional genomic studies of B. longum subsp. longumIMPORTANCE Several hundred species of bacteria colonize the mammalian intestine. However, the genes that enable such bacteria to colonize and thrive in the intestine remain largely unexplored. Transposon mutagenesis, combined with next-generation sequencing, is a promising tool to comprehensively identify these genes but has so far been applied only to a small number of intestinal bacterial species. In this study, a transposon mutagenesis system was established for Bifidobacterium longum subsp. longum, a representative health-promoting Bifidobacterium species. The system enables the identification of genes that promote colonization and survival in the intestine and should help illuminate the physiology of this species.

Published

2018

30. Function and structure of GH13_31 α-glucosidase with high α-(1→4)-glucosidic linkage specificity and transglucosylation activity

Author

Wataru Saburi, Koji Kato, Waraporn Auiewiriyanukul, Haruhide Mori, and Min Yao

Subjects

0301 basic medicine, Models, Molecular, Glycosylation, Stereochemistry, 030106 microbiology, Mutant, Biophysics, Bacillus, Biochemistry, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Hydrolysis, Structure-Activity Relationship, Glucosides, Structural Biology, Catalytic Domain, Hydrolase, Genetics, Amino Acid Sequence, Molecular Biology, chemistry.chemical_classification, biology, Chemistry, Substrate (chemistry), alpha-Glucosidases, Cell Biology, Maltose, Acceptor, Kinetics, 030104 developmental biology, Enzyme, Carbohydrate Sequence, Alpha-glucosidase, biology.protein, Mutagenesis, Site-Directed, Carbohydrate Metabolism

Abstract

α-Glucosidase hydrolyzes α-glucosides and transfers α-glucosyl residues to an acceptor through transglucosylation. In this study, GH13_31 α-glucosidase BspAG13_31A with high transglucosylation activity is reported in Bacillus sp. AHU2216 and biochemically and structurally characterized. This enzyme is specific to α-(1→4)-glucosidic linkage as substrates and transglucosylation products. Maltose is the most preferred substrate. Crystal structures of BspAG13_31A wild-type for the substrate-free form and inactive acid/base mutant E256Q in complexes with maltooligosaccharides were solved at 1.6-2.5 A resolution. BspAG13_31A has a catalytic domain folded by an (β/α)8 -barrel. In subsite +1, Ala200 and His203 on β→α loop 4 and Asn258 on β→α loop 5 are involved in the recognition of maltooligosaccharides. Structural basis for specificity of GH13_31 enzymes to α-(1→4)-glucosidic linkage is first described.

Published

2018

31. A Transposon Mutagenesis System for Bifidobacterium longum subsp. longum Based on an IS

Author

Mikiyasu, Sakanaka, Shingo, Nakakawaji, Shin, Nakajima, Satoru, Fukiya, Arisa, Abe, Wataru, Saburi, Haruhide, Mori, and Atsushi, Yokota

Subjects

food and beverages, Transposases, Trehalose, alpha-Glucosidases, Genetics and Molecular Biology, Sequence Analysis, DNA, Isomaltose, Bifidobacterium longum, Gastrointestinal Microbiome, Intestines, fluids and secretions, Mutagenesis, DNA Transposable Elements, bacteria, Humans, Genome, Bacterial, Plasmids

Abstract

Several hundred species of bacteria colonize the mammalian intestine. However, the genes that enable such bacteria to colonize and thrive in the intestine remain largely unexplored. Transposon mutagenesis, combined with next-generation sequencing, is a promising tool to comprehensively identify these genes but has so far been applied only to a small number of intestinal bacterial species. In this study, a transposon mutagenesis system was established for Bifidobacterium longum subsp. longum, a representative health-promoting Bifidobacterium species. The system enables the identification of genes that promote colonization and survival in the intestine and should help illuminate the physiology of this species.

Published

2018

32. Identification of rice Os4BGlu13 as a β-glucosidase which hydrolyzes gibberellin A4 1-O-β-d-glucosyl ester, in addition to tuberonic acid glucoside and salicylic acid derivative glucosides

Author

Ryosuke Takeda, James R. Ketudat Cairns, Haruhide Mori, Sittiruk Roytrakul, Wataru Saburi, Sompong Sansenya, Chantragan Srisomsap, Watsamon Ekkhara, Hideyuki Matsuura, and Yanling Hua

Subjects

Recombinant Fusion Proteins, Biophysics, Cyclopentanes, Biochemistry, Mass Spectrometry, Substrate Specificity, chemistry.chemical_compound, Hydrolysis, Glucosides, Glycoside hydrolase, Enzyme kinetics, Molecular Biology, chemistry.chemical_classification, beta-Glucosidase, Glycoside, Esters, Oryza, Oligosaccharide, Gibberellins, Salicylates, Enzyme, chemistry, Electrophoresis, Polyacrylamide Gel, Gibberellin, Salicylic acid, Chromatography, Liquid

Abstract

Gibberellin 1-O-β-d-glucose ester hydrolysis activity has been detected in rice seedling extracts, but no enzyme responsible for this activity has ever been purified and identified. Therefore, gibberellin A4 glucosyl ester (GA4-GE) β-d-glucosidase activity was purified from ten-day rice seedling stems and leaves. The family 1 glycoside hydrolase Os4BGlu13 was identified in the final purification fraction. The Os4BGlu13 cDNA was amplified from rice seedlings and expressed as an N-terminal thioredoxin-tagged fusion protein in Escherichia coli. The purified recombinant Os4BGlu13 protein (rOs4BGlu13) had an optimum pH of 4.5, for hydrolysis of p-nitrophenyl β-d-glucopyranoside (pNPGlc), which was the best substrate identified, with a kcat/Km of 637 mM(-1) s(-1). rOs4BGlu13 hydrolyzed helicin best among natural glycosides tested (kcat/Km of 74.4 mM(-1) s(-1)). Os4BGlu13 was previously designated tuberonic acid glucoside (TAG) β-glucosidase (TAGG), and here the kcat/Km of rOsBGlu13 for TAG was 6.68 mM(-1) s(-1), while that for GA4-GE was 3.63 mM(-1) s(-1) and for salicylic acid glucoside (SAG) is 0.88 mM(-1) s(-1). rOs4BGlu13 also hydrolyzed oligosaccharides, with preference for short β-(1 → 3)-linked over β-(1 → 4)-linked glucooligosaccharides. The enzymatic data suggests that Os4BGlu13 may contribute to TAG, SAG, oligosaccharide and GA4-GE hydrolysis in the rice plant, although helicin or a similar compound may be its primary target.

Published

2015

33. Functional reassignment of Cellvibrio vulgaris EpiA to cellobiose 2-epimerase and an evaluation of the biochemical functions of the 4-O-β-<scp>d</scp>-mannosyl-<scp>d</scp>-glucose phosphorylase-like protein, UnkA

Author

Wataru Saburi, Mamoru Nishimoto, Yuka Tanaka, Sota Inoue, Motomitsu Kitaoka, Hirohiko Muto, Haruhide Mori, and Rei Odaka

Subjects

Cellobiose, Phosphorylases, EPIA, Racemases and Epimerases, Biology, medicine.disease_cause, Applied Microbiology and Biotechnology, Biochemistry, Substrate Specificity, Analytical Chemistry, law.invention, Mannans, Cellvibrio, chemistry.chemical_compound, Glycogen phosphorylase, D-Glucose, law, Enzyme Stability, Gene cluster, medicine, Molecular Biology, Escherichia coli, Peptide sequence, Organic Chemistry, Temperature, General Medicine, Hydrogen-Ion Concentration, Recombinant Proteins, Kinetics, chemistry, Recombinant DNA, Biotechnology

Abstract

The aerobic soil bacterium Cellvibrio vulgaris has a β-mannan-degradation gene cluster, including unkA, epiA, man5A, and aga27A. Among these genes, epiA has been assigned to encode an epimerase for converting d-mannose to d-glucose, even though the amino acid sequence of EpiA is similar to that of cellobiose 2-epimerases (CEs). UnkA, whose function currently remains unknown, shows a high sequence identity to 4-O-β-d-mannosyl-d-glucose phosphorylase. In this study, we have investigated CE activity of EpiA and the general characteristics of UnkA using recombinant proteins from Escherichia coli. Recombinant EpiA catalyzed the epimerization of the 2-OH group of sugar residue at the reducing end of cellobiose, lactose, and β-(1→4)-mannobiose in a similar manner to other CEs. Furthermore, the reaction efficiency of EpiA for β-(1→4)-mannobiose was 5.5 × 104-fold higher than it was for d-mannose. Recombinant UnkA phosphorolyzed β-d-mannosyl-(1→4)-d-glucose and specifically utilized d-glucose as an acceptor in the reverse reaction, which indicated that UnkA is a typical 4-O-β-d-mannosyl-d-glucose phosphorylase.

Published

2015

34. A model system for studying plant-microbe interactions under snow.

Author

Chikako Kuwabara, Kentaro Sasaki, Natsuki Umeki, Tamotsu Hoshino, Wataru Saburi, Hirokazu Matsui, and Ryozo Imai

Published

2021

35. Ten years of CAZypedia: a living encyclopedia of carbohydrate-active enzymes

Author

Štefan Janeček, Rohan J. Williams, Geoff Pincher, Darrell Cockburn, Gurvan Michel, Wataru Saburi, David R. Rose, Brian P. Rempel, Glyn R. Hemsworth, Wim Van den Ende, Jerry Ståhlberg, Leila LoLeggio, Tom Wennekes, Kiyohiko Igarashi, Cedric Montanier, Etienne Rebuffet, Naotake Konno, Harry J. Gilbert, Markus Linder, Ed Bayer, Tirso Pons, Jan-Hendrik Hehemann, Tomomi Sumida, Thierry Fontaine, Takane Katayama, Elizabeth Ficko-Blean, Florence Vincent, Zui Fujimoto, Masafumi Hidaka, Kyle Robinson, Ana R. Luís, Yuichi Sakamoto, Bernard Henrissat, Gustav Vaaje-Kolstad, Jens M. Eklöf, Ian R. Greig, Harry Brumer, Ryuichiro Suzuki, Mats Sandgren, Takashi Tonozuka, Ryszard Brzezinski, Brian L. Mark, Bareket Dassa, Haruhide Mori, Junho Lee, Vivian L. Y. Yip, Birte Svensson, Wade Abbott, Alfons K. G. Felice, Juha Rouvinen, Takayuki Ohnuma, Satoshi Kaneko, Franz J. St John, Ramon Hurtado-Guerrero, Pedro M. Coutinho, Sine Larsen, Gideon J. Davies, Yuval Shoham, Kiyotaka Fujita, Warren W. Wakarchuk, Fathima Aidha Shaikh, Alisdair B. Boraston, Breeanna R. Urbanowicz, Vincent G. H. Eijsink, Daniel Kracher, Beatrice Cobucci-Ponzano, Ethan D. Goddard-Borger, Anthony J. Clarke, David J. Vocadlo, Katsuro Yaoi, Seino A. K. Jongkees, Anna A. Kulminskaya, Roland Ludwig, Mirko M. Maksimainen, Magali Remaud-Simeon, Edward J. Taylor, Motomitsu Kitaoka, Spencer J. Williams, Shinya Fushinobu, Marco Moracci, David Wilson, Richard McLean, Toki Taira, Jean-Guy Berrin, Ran Zhang, Hiroyuki Nakai, Tracey M. Gloster, Peter J. Reilly, Wim Nerinckx, Takuya Ishida, Alicia Lammerts van Bueren, Orly Alber, Mirjam Czjzek, Kathleen Piens, Annabelle Varrot, Stephen G. Withers, Nathalie Juge, Maxime Versluys, Gerlind Sulzenbacher, Richard W. Pickersgill, Michael D. L. Suits, Agriculture and Agri-Food [Ottawa] (AAFC), Weizmann Institute of Science [Rehovot, Israël], Laboratoire d'Ingénierie des Systèmes Biologiques et des Procédés (LISBP), Institut National de la Recherche Agronomique (INRA)-Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Centre National de la Recherche Scientifique (CNRS), University of Victoria [Canada] (UVIC), University of British Columbia, Université de Sherbrooke (UdeS), University of Guelph, National Research Council (CNR), Pennsylvania State University (Penn State), Penn State System, Aix Marseille Université (AMU), Laboratoire de Biologie Intégrative des Modèles Marins (LBI2M), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Station biologique de Roscoff (SBR), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Sorbonne Université (SU), University of York, Norwegian University of Life Sciences (NMBU), University of Vienna [Vienna], University of Adelaide, Institut Pasteur [Paris], National Agriculture and Food Research Organization (NARO), Kagoshima University, University of Tokyo, Newcastle University, University of St Andrews [Scotland], The Walter and Eliza Hall Institute of Medical Research (WEHI), Simon Fraser University (SFU.ca), Max Planck Institute for Marine Microbiology, Max-Planck-Gesellschaft, University of Leeds, University of Zaragoza - Universidad de Zaragoza [Zaragoza], Slovak Academy of Sciences (SAS), Quadram Institute, University of the Ryukyus [Okinawa], Ishikawa Prefectural University, Utsunomiya University [Utsunomiya], St Petersburg Nuclear Physics Institute, University of Groningen, Aalto University, University of Copenhagen = Københavns Universitet (KU), University of Lisbon, University of Oulu, University of Manitoba [Winnipeg], University of Lethbridge, Hokkaido University [Sapporo, Japan], Niigata University, Ghent University, Kinki University, Queen Mary University of London (QMUL), Sveriges lantbruksuniversitet, National Center for Biotechnology, Centre de Recherche en Cancérologie de Marseille (CRCM), Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut Paoli-Calmettes, Fédération nationale des Centres de lutte contre le Cancer (FNCLCC)-Fédération nationale des Centres de lutte contre le Cancer (FNCLCC)-Aix Marseille Université (AMU), Iowa State University (ISU), Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA), University of Waterloo [Waterloo], University of Eastern Finland, Iwate Biotechnology Research Center (IBRC), Technion - Israel Institute of Technology [Haifa], United States Department of Agriculture, Wilfrid Laurier University (WLU), Architecture et fonction des macromolécules biologiques (AFMB), Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA), Institut National de la Recherche Agronomique (INRA), RIKEN - Institute of Physical and Chemical Research [Japon] (RIKEN), Akita University, Danmarks Tekniske Universitet (DTU), University of Lincoln, Tokyo University of Agriculture and Technology (TUAT), Univ Georgia, University of Georgia [USA], Université Catholique de Louvain = Catholic University of Louvain (UCL), Centre de Recherches sur les Macromolécules Végétales (CERMAV ), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Ryerson University, Utrecht University [Utrecht], University of Melbourne, Cornell University [New York], National Institute of Advanced Industrial Science and Technology (AIST), Natural Sciences and Engineering Research Council of Canada (NSERC), Agriculture and Agri-Food (AAFC), Institut National des Sciences Appliquées (INSA)-Université de Toulouse (UT)-Institut National des Sciences Appliquées (INSA)-Université de Toulouse (UT)-Centre National de la Recherche Scientifique (CNRS), Institut Pasteur [Paris] (IP), Biotechnology and Biological Sciences Research Council (BBSRC), University of Copenhagen = Københavns Universitet (UCPH), Universidade de Lisboa = University of Lisbon (ULISBOA), Universiteit Gent = Ghent University (UGENT), Aix Marseille Université (AMU)-Institut Paoli-Calmettes, Fédération nationale des Centres de lutte contre le Cancer (FNCLCC)-Fédération nationale des Centres de lutte contre le Cancer (FNCLCC)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Institut National des Sciences Appliquées (INSA)-Université de Toulouse (UT), Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Danmarks Tekniske Universitet = Technical University of Denmark (DTU), Weizmann Institute of Science, Centre National de la Recherche Scientifique (CNRS)-Institut National des Sciences Appliquées - Toulouse (INSA Toulouse), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Institut National de la Recherche Agronomique (INRA), University of Victoria, Sherbrooke University, Sorbonne Universités, University of Vienna, National Agriculture and Food Research Organization, University of St Andrews, Walter and Eliza Hall Institute of Medical Research (WEHI), Slovak Academy of Sciences, Utsunomiya University, Hokkaido University, Iwate Biotechnol Res Ctr, Technion – Israel Institute of Technology, Akita Prefectural University, Université Catholique de Louvain (UCL), Centre de Recherches sur les Macromolécules Végétales (CERMAV), Université Joseph Fourier - Grenoble 1 (UJF)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), Université Grenoble Alpes (UGA), Cornell University, Laboratoire Départemental Vétérinaire et d'Hygiène Alimentaire des Hautes Alpes, and Moracci, M

Subjects

0301 basic medicine, History, Carbohydrate, CAZy, Bioinformatics, [SDV]Life Sciences [q-bio], 030106 microbiology, Polysaccharide-Lyases, Glycobiology, Carbohydrates, Glycosyltransferases/chemistry, Computational biology, Biology, Esterase, Biochemistry, History, 21st Century, Databases, 03 medical and health sciences, glycobiology, Esterases/chemistry, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Carbohydrates/chemistry, Glycoscience, Databases, Protein, ComputingMilieux_MISCELLANEOUS, bioinformatic, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], Protein, Polysaccharide-Lyases/chemistry, biocuration, Esterases, glycoscience, Glycosyltransferases, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, bioinformatics, 21st Century, Biocuration, [SDV.BBM.BP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biophysics, 030104 developmental biology, carbohydrate-active enzymes, Encyclopedia, Carbohydrate-active enzymes, carbohydrate-active enzyme, Carbohydrate active enzymes, Glycosyltransferase

Abstract

CAZypedia was initiated in 2007 to create a comprehensive, living encyclopedia of the carbohydrate-active enzymes (CAZymes) and associated carbohydrate-binding modules involved in the synthesis, modification, and degradation of complex carbohydrates. CAZypedia is closely connected with the actively-curated CAZy database, which provides a sequence-based foundation for the biochemical, mechanistic, and structural characterization of these diverse proteins. Now celebrating its 10th anniversary online, CAZypedia is a successful example of dynamic, community-driven, and expert-based biocuration. CAZypedia is an open-access resource available at URL http://www.cazypedia.org.

Published

2018

36. Structural elements responsible for the glucosidic linkage‐selectivity of a glycoside hydrolase family 13 exo‐glucosidase

Author

Haruhide Mori, Hironori Hondoh, Hiroaki Rachi-Otsuka, Wataru Saburi, Masayuki Okuyama, and Atsuo Kimura

Subjects

Glycoside Hydrolases, Stereochemistry, Substrate specificity, Biophysics, medicine.disease_cause, Biochemistry, Streptococcus mutans, alpha-Glucosidase, Dextran glucosidase, chemistry.chemical_compound, Bacterial Proteins, Structural Biology, Catalytic Domain, Genetics, medicine, Glycoside hydrolase, Enzyme kinetics, Maltose, Molecular Biology, Glycoside hydrolase family 13, Mutation, biology, Chemistry, Cell Biology, Isomaltose, biology.organism_classification, Oligo-1,6-glucosidase, Kinetics, α-Glucosidase, Alpha-glucosidase, Mutagenesis, Site-Directed, biology.protein, Selectivity

Abstract

Glycoside hydrolase family 13 contains exo-glucosidases specific for alpha-(1 -> 4)- and alpha-(1 -> 6)-linkages including alpha-glucosidase, oligo-1,6-glucosidase, and dextran glucosidase. The alpha-(1 -> 6)-linkage selectivity of Streptococcus mutans dextran glucosidase was altered to alpha-(1 -> 4)-linkage selectivity through site-directed mutations at Val195, Lys275, and Glu371. V195A showed 1300-fold higher k(cat)/K-m for maltose than wild-type, but its k(cat)/K-m for isomaltose remained 2-fold higher than for maltose. K275A and E371A combined with V195A mutation only decreased isomaltase activity. V195A/K275A, V195A/E371A, and V195A/K275A/E371A showed 27-, 26-, and 73-fold higher k(cat)/K-m for maltose than for isomaltose, respectively. Consequently, the three residues are structural elements for recognition of the alpha-(1 -> 6)-glucosidic linkage. (C) 2015 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.

Published

2015

37. Evaluation of acceptor selectivity of Lactococcus lactis ssp. lactis trehalose 6-phosphate phosphorylase in the reverse phosphorolysis and synthesis of a new sugar phosphate

Author

Haruhide Mori, Wataru Saburi, Yodai Taguchi, and Ryozo Imai

Subjects

0301 basic medicine, Gene Expression, Biology, Applied Microbiology and Biotechnology, Biochemistry, Analytical Chemistry, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Glycogen phosphorylase, Bacterial Proteins, Escherichia coli, Glycoside hydrolase, Cloning, Molecular, Molecular Biology, Ternary complex, Phosphorolysis, chemistry.chemical_classification, Sugar phosphates, Mannosephosphates, Hydrolysis, Organic Chemistry, Lactococcus lactis, Glucosephosphates, Temperature, Trehalose, General Medicine, PEP group translocation, Hydrogen-Ion Concentration, biology.organism_classification, Recombinant Proteins, Kinetics, 030104 developmental biology, chemistry, Glucosyltransferases, Sugar Phosphates, Biotechnology

Abstract

Trehalose 6-phosphate phosphorylase (TrePP), a member of glycoside hydrolase family 65, catalyzes the reversible phosphorolysis of trehalose 6-phosphate (Tre6P) with inversion of the anomeric configuration to produce β-d-glucose 1-phosphate (β-Glc1P) and d-glucose 6-phosphate (Glc6P). TrePP in Lactococcus lactis ssp. lactis (LlTrePP) is, alongside the phosphotransferase system, involved in the metabolism of trehalose. In this study, recombinant LlTrePP was produced and characterized. It showed its highest reverse phosphorolytic activity at pH 4.8 and 40°C, and was stable in the pH range 5.0–8.0 and at up to 30°C. Kinetic analyses indicated that reverse phosphorolysis of Tre6P proceeded through a sequential bi bi mechanism involving the formation of a ternary complex of the enzyme, β-Glc1P, and Glc6P. Suitable acceptor substrates were Glc6P, and, at a low level, d-mannose 6-phosphate (Man6P). From β-Glc1P and Man6P, a novel sugar phosphate, α-d-Glcp-(1↔1)-α-d-Manp6P, was synthesized with 51% yield. A novel sugar phosphate, α-d-Glcp-(1↔1)-α-d-Manp6P, was synthesized by Lactococcus lactis ssp. lactis trehalose 6-phosphate phosphorylase.

Published

2017

38. Efficient one-pot enzymatic synthesis of trehalose 6-phosphate using GH65 α-glucoside phosphorylases

Author

Yodai Taguchi, Haruhide Mori, Ryozo Imai, and Wataru Saburi

Subjects

Trehalose 6-phosphate, Glycoside hydrolase family 65, 010402 general chemistry, 01 natural sciences, Biochemistry, Maltose phosphorylase, Phosphates, Analytical Chemistry, chemistry.chemical_compound, Glycogen phosphorylase, Bacterial Proteins, Glucoside, Yeasts, Cloning, Molecular, Phosphorolysis, biology, 010405 organic chemistry, Organic Chemistry, Lactococcus lactis, Glucosephosphates, Trehalose, General Medicine, Maltose, biology.organism_classification, 0104 chemical sciences, chemistry, Phosphoglucomutase, Glucosyltransferases, Trehalose 6-phosphate phosphorylase, Glucose-6-Phosphatase, Carbohydrate Metabolism, Sugar Phosphates

Abstract

Trehalose 6-phosphate (Tre6P) is an important intermediate for trehalose biosynthesis. Recent researches have revealed that Tre6P is an endogenous signaling molecule that regulates plant development and stress responses. The necessity of Tre6P in physiological studies is expected to be increasing. To achieve the cost-effective production of Tre6P, a novel approach is required. In this study, we utilized trehalose 6-phosphate phosphorylase (TrePP) from Lactococcus lactis to produce Tre6P. In the reverse phosphorolysis by the TrePP, 91.9 mM Tre6P was produced from 100 mM β-glucose 1-phosphate (β-Glc1P) and 100 mM glucose 6-phosphate (Glc6P). The one-pot reaction of TrePP and maltose phosphorylase (MP) enabled production of 65 mM Tre6P from 100 mM maltose, 100 mM Glc6P, and 20 mM inorganic phosphate. Addition of β-phosphoglucomutase to this reaction produced Glc6P from β-Glc1P and thus reduced requirement of Glc6P as a starting material. Within the range of 20–469 mM inorganic phosphate tested, the 54 mM concentration yielded the highest amount of Tre6P (33 mM). Addition of yeast increased the yield because of its glucose consumption. Finally, from 100 mmol maltose and 60 mmol inorganic phosphate, we successfully achieved production of 37.5 mmol Tre6P in a one-pot reaction (100 mL), and 9.4 g Tre6P dipotassium salt was obtained.

Published

2020

39. Acidophilic β-Galactosidase from Aspergillus niger AHU7120 with Lactose Hydrolytic Activity Under Simulated Gastric Conditions

Author

Wataru Saburi, Hirokazu Matsui, Haruhide Mori, and Hiroshi Ueno

Subjects

Lactose intolerance, milk, biology, Chemistry, Aspergillus niger, β-galactosidase, biology.organism_classification, medicine.disease, lactose, Hydrolysis, chemistry.chemical_compound, lactose intolerance, Biochemistry, medicine, Lactose

Abstract

Acidophilic β-galactosidase is a useful enzyme as digestive supplement used to alleviate symptoms of lactose intolerance. Aspergilli are the source of several acidophilic β-galactosidases that retain enzymatic activity under gastric conditions. In this study, we investigated the extracellular acidophilic β-galactosidase activity of six Aspergillus niger strains, AHU7104, AHU7120, AHU7217, AHU7294, AHU7295 and AHU7296; A. niger AHU7120 was selected as an enzyme source. β-Galactosidase from A. niger AHU7120 (AnBGal) was purified from culture supernatant. Its N-terminal sequence was identical to that of An01g12150, which belongs to the glycoside hydrolase family 35, from A. niger CBS 513.88. The DNA sequence of AnBGal was identical to An01g12150. Recombinant AnBGal (rAnBGal) harboring yeast α-factor signal sequence was expressed in Pichia pastoris, and 21.9 mg of purified rAnBGal with 129 U/mg of enzyme activity was isolated from 200 mL of culture supernatant. Native and recombinant AnBGal enzymes showed similar pH optima, pH stability, and kinetics for p-nitrophenyl β-D-galactopyranoside and lactose; rAnBGal showed slightly lower thermal stability than the native enzyme. Lactose in milk was rapidly degraded by rAnBGal at higher pH values (range, 2.0‒3.5), consistent with the pH optimum of AnBGal. We estimated that 3.5 μM AnBGal may degrade ≥ 66% of lactose before gastric half-emptying of ingested milk. These data indicate that AnBGal may help alleviate symptoms of lactose intolerance.

Published

2014

40. Enhancement of hydrolytic activity of thermophilic alkalophilic α-amylase from Bacillus sp. AAH-31 through optimization of amino acid residues surrounding the substrate binding site

Author

Atsushi Mukai, Naoki Morimoto, Haruhide Mori, Toshihiko Takehana, Hirokazu Matsui, Seiji Koike, Naoya Tamamura, and Wataru Saburi

Subjects

chemistry.chemical_classification, Environmental Engineering, biology, Stereochemistry, Thermophile, Biomedical Engineering, Wild type, Substrate (chemistry), Bioengineering, Amino acid, Enzyme, chemistry, Biochemistry, biology.protein, Amylase, Binding site, Alpha-amylase, Biotechnology

Abstract

The hydrolytic activity of a thermophilic alkalophilic α-amylase from Bacillus sp. AAH-31 (AmyL) toward soluble starch was enhanced through optimization of amino acid (aa) residues situated near the substrate binding site. Twenty-four selected aa residues were replaced with Ala, and Gly429 and Gly550 were altered to Lys and Glu, respectively, based on comparison of AmyL's aa sequence with related enzymes. Y426A, H431A, I509A, and K549A showed notably higher activity than the wild type at 162–254% of wild-type activity. Tyr426, His431, and Ile509 were predicted to be located near subsite −2, while Lys549 was near subsite +2. Ser, Ala, Ala, and Met were found to be the best aa residues for the positions of Tyr426, His431, Ile509, and Lys549, respectively. Combinations of the optimized single mutations at distant positions were effective in enhancing catalytic activity. The double-mutant enzymes Y426S/K549M, H431A/K549M, and I509A/K549M, combining two of the selected single mutations, showed 340%, 252%, and 271% of wild type activity, respectively. Triple and quadruple-mutant enzymes of the selected mutations did not show higher activity than the best double-mutant, Y426S/K549M.

Published

2014

41. Structural Insights into the Epimerization of β-1,4-Linked Oligosaccharides Catalyzed by Cellobiose 2-Epimerase, the Sole Enzyme Epimerizing Non-anomeric Hydroxyl Groups of Unmodified Sugars

Author

Haruhide Mori, Takaaki Fujiwara, Wataru Saburi, Hirokazu Matsui, and Min Yao

Subjects

Anomer, Stereochemistry, Glycobiology, Bacterial Metabolism, Enzyme Mechanisms, Oligosaccharides, Rhodothermus, Isomerase, Cellobiose, Biochemistry, Catalysis, Protein Structure, Secondary, Reversible reaction, Residue (chemistry), chemistry.chemical_compound, Deprotonation, Bacterial Proteins, Epimerization, Molecular Biology, AGE Superfamily, Cellobiitol, Ligand, Hydrogen bond, Chemistry, Cell Biology, Cellobiose 2-Epimerase, Glucose, Crystal Structure, Enzymology, Carbohydrate-binding Protein, Carbohydrate Epimerases

Abstract

Cellobiose 2-epimerase (CE) reversibly converts d-glucose residues into d-mannose residues at the reducing end of unmodified β1,4-linked oligosaccharides, including β-1,4-mannobiose, cellobiose, and lactose. CE is responsible for conversion of β1,4-mannobiose to 4-O-β-d-mannosyl-d-glucose in mannan metabolism. However, the detailed catalytic mechanism of CE is unclear due to the lack of structural data in complex with ligands. We determined the crystal structures of halothermophile Rhodothermus marinus CE (RmCE) in complex with substrates/products or intermediate analogs, and its apo form. The structures in complex with the substrates/products indicated that the residues in the β5-β6 loop as well as those in the inner six helices form the catalytic site. Trp-322 and Trp-385 interact with reducing and non-reducing end parts of these ligands, respectively, by stacking interactions. The architecture of the catalytic site also provided insights into the mechanism of reversible epimerization. His-259 abstracts the H2 proton of the d-mannose residue at the reducing end, and consistently forms the cis-enediol intermediate by facilitated depolarization of the 2-OH group mediated by hydrogen bonding interaction with His-200. His-390 subsequently donates the proton to the C2 atom of the intermediate to form a d-glucose residue. The reverse reaction is mediated by these three histidines with the inverse roles of acid/base catalysts. The conformation of cellobiitol demonstrated that the deprotonation/reprotonation step is coupled with rotation of the C2-C3 bond of the open form of the ligand. Moreover, it is postulated that His-390 is closely related to ring opening/closure by transferring a proton between the O5 and O1 atoms of the ligand.

Published

2014

42. Characterization of a thermophilic 4-O-β-<scp>d</scp>-mannosyl-<scp>d</scp>-glucose phosphorylase from Rhodothermus marinus

Author

Ken Hamura, Haruhide Mori, Nongluck Jaito, Mamoru Nishimoto, Motomitsu Kitaoka, Wataru Saburi, Yusuke Kido, Hirokazu Matsui, and Rei Odaka

Subjects

Molecular Sequence Data, Rhodothermus, Cellobiose, Biology, Mannosyltransferases, Applied Microbiology and Biotechnology, Biochemistry, Substrate Specificity, Analytical Chemistry, Mannans, chemistry.chemical_compound, Glycogen phosphorylase, D-Glucose, Enzyme Stability, Extracellular, Amino Acid Sequence, Phosphorylation, Molecular Biology, Ternary complex, Mannan, Phosphorolysis, Thermophile, Organic Chemistry, Temperature, General Medicine, Hydrogen-Ion Concentration, Kinetics, chemistry, Biotechnology

Abstract

4-O-β-d-Mannosyl-d-glucose phosphorylase (MGP), found in anaerobes, converts 4-O-β-d-mannosyl-d-glucose (Man-Glc) to α-d-mannosyl phosphate and d-glucose. It participates in mannan metabolism with cellobiose 2-epimerase (CE), which converts β-1,4-mannobiose to Man-Glc. A putative MGP gene is present in the genome of the thermophilic aerobe Rhodothermus marinus (Rm) upstream of the gene encoding CE. Konjac glucomannan enhanced production by R. marinus of MGP, CE, and extracellular mannan endo-1,4-β-mannosidase. Recombinant RmMGP catalyzed the phosphorolysis of Man-Glc through a sequential bi–bi mechanism involving ternary complex formation. Its molecular masses were 45 and 222 kDa under denaturing and nondenaturing conditions, respectively. Its pH and temperature optima were 6.5 and 75 °C, and it was stable between pH 5.5–8.3 and below 80 °C. In the reverse reaction, RmMGP had higher acceptor preferences for 6-deoxy-d-glucose and d-xylose than R. albus NE1 MGP. In contrast to R. albus NE1 MGP, RmMGP utilized methyl β-d-glucoside and 1,5-anhydro-d-glucitol as acceptor substrates.

Published

2014

43. Modulation of acceptor specificity of Ruminococcus albus cellobiose phosphorylase through site-directed mutagenesis

Author

Wataru Saburi, Hirokazu Matsui, Haruhide Mori, and Ken Hamura

Subjects

Time Factors, Mutant, Glucose 1-phosphate, Oligosaccharides, Cellobiose, Biochemistry, Laminaribiose phosphorylase, Substrate Specificity, Oligosaccharide synthesis, Analytical Chemistry, Acceptor specificity, chemistry.chemical_compound, Cellobiose phosphorylase, Ruminococcus, Site-directed mutagenesis, Glycoside hydrolase family 94, Phosphorolysis, Chemistry, Organic Chemistry, Temperature, Wild type, General Medicine, Hydrogen-Ion Concentration, Glucosyltransferases, Biocatalysis, Mutagenesis, Site-Directed

Abstract

Cellobiose phosphorylase (EC 2.4.1.20, CBP) catalyzes the reversible phosphorolysis of cellobiose to alpha-D-glucose 1-phosphate (Glc1P) and D-glucose. Cys485, Tyr648, and Glu653 of CBP from Ruminococcus albus, situated at the +1 subsite, were mutated to modulate acceptor specificity. C485A, Y648F, and Y648V were active enough for analysis. Their acceptor specificities were compared with the wild type based on the apparent kinetic parameters determined in the presence of 10 mM Glc1P. C485A showed higher preference for D-glucosamine than the wild type. Apparent k(cat)/K-m values of Y648F for D-mannose and 2-deoxy-D-glucose were 8.2- and 4.0-fold higher than those of the wild type, respectively. Y648V had synthetic activity toward N-acetyl-D-glucosamine, while the other variants did not. The oligosaccharide production in the presence of the same concentrations of wild type and each mutant was compared. C485A produced 4-O-beta-D-glucopyranosyl-D-glucosamine from 10 mM Glc1P and D-glucosamine at a rate similar to the wild type. Y648F and Y648V produced 4-O-beta-D-glucopyranosyl-D-mannose and 4-O-beta-D-glucopyranosyl-N-acetyl-D-glucosamine much more rapidly than the wild type when D-mannose and N-acetyl-D-glucosamine were used as acceptors, respectively. After a 4 h reaction, the amounts of 4-O-beta-D-glucopyranosyl-D-mannose and 4-O-beta-D-glucopyranosyl-N-acetyl-D-glucosamine produced by Y648F and Y648V were 5.9- and 12-fold higher than the wild type, respectively. (C) 2013 Elsevier Ltd. All rights reserved.

Published

2013

44. Characterization ofRuminococcus albuscellodextrin phosphorylase and identification of a key phenylalanine residue for acceptor specificity and affinity to the phosphate group

Author

Haruhide Mori, Hirokazu Matsui, Tatsuya Sawano, Wataru Saburi, and Ken Hamura

Subjects

Cellodextrin phosphorylase, Cellobiose, Sophorose, Stereochemistry, Phenylalanine, Oligosaccharides, Biochemistry, Substrate Specificity, Glycogen phosphorylase, chemistry.chemical_compound, Bacterial Proteins, Cellobiose phosphorylase, Dextrins, Ruminococcus, Escherichia coli, Cellulose, Molecular Biology, Laminaribiose, Phylogeny, Phosphorolysis, Hydrolysis, Cell Biology, Phosphate, Recombinant Proteins, Kinetics, chemistry, Glucosyltransferases, Mutation, Thermodynamics

Abstract

Ruminococcus albus has the ability to intracellularly degrade cello-oligosaccharides primarily via phosphorolysis. In this study, the enzymatic characteristics of R. albus cellodextrin phosphorylase (RaCDP), which is a member of glycoside hydrolase family 94, was investigated. RaCDP catalyzes the phosphorolysis of cellotriose through an ordered 'bi bi' mechanism in which cellotriose binds to RaCDP before inorganic phosphate, and then cellobiose and glucose 1-phosphate (Glc1P) are released in that order. Among the cello-oligosaccharides tested, RaCDP had the highest phosphorolytic and synthetic activities towards cellohexaose and cellopentaose, respectively. RaCDP successively transferred glucosyl residues from Glc1P to the growing cello-oligosaccharide chain, and insoluble cello-oligosaccharides comprising a mean of eight residues were produced. Sophorose, laminaribiose, β-1,4-xylobiose, β-1,4-mannobiose and cellobiitol served as acceptors for RaCDP. RaCDP had very low affinity for phosphate groups in both the phosphorolysis and synthesis directions. A sequence comparison revealed that RaCDP has Gln at position 646 where His is normally conserved in the phosphate binding sites of related enzymes. A Q646H mutant showed approximately twofold lower apparent K(m) values for inorganic phosphate and Glc1P than the wild-type. RaCDP has Phe at position 633 corresponding to Tyr and Val in the +1 subsites of cellobiose phosphorylase and N,N'-diacetylchitobiose phosphorylase, respectively. A F633Y mutant showed higher preference for cellobiose over β-1,4-mannobiose as an acceptor substrate in the synthetic reaction than the wild-type. Furthermore, the F633Y mutant showed 75- and 1100-fold lower apparent Km values for inorganic phosphate and Glc1P, respectively, in phosphorolysis and synthesis of cellotriose.

Published

2013

45. Identification of Rice β-Glucosidase with High Hydrolytic Activity towards Salicylic Acid β-<scp>D</scp>-Glucoside

Author

James R. Ketudat Cairns, Ryosuke Takeda, Wataru Saburi, Shinji Wakuta, Haruhide Mori, Sompong Sansenya, Ryozo Imai, Kensuke Nabeta, Hirokazu Matsui, Nami Himeno, and Hideyuki Matsuura

Subjects

tuberonic acid, substrate specificity, salicylic acid, Molecular Sequence Data, Applied Microbiology and Biotechnology, Biochemistry, Pichia, Analytical Chemistry, Pichia pastoris, chemistry.chemical_compound, Hydrolysis, Glucosides, Glucoside, Amino Acid Sequence, Molecular Biology, Ammonium sulfate precipitation, chemistry.chemical_classification, Methyl jasmonate, biology, beta-Glucosidase, rice, Organic Chemistry, Temperature, food and beverages, Substrate (chemistry), Oryza, General Medicine, Hydrogen-Ion Concentration, biology.organism_classification, Salicylates, Enzyme, chemistry, β-glucosidase, Salicylic acid, Biotechnology

Abstract

β-Glucosidases (EC 3.2.1.21) split β-glucosidic linkages at the non-reducing end of glucosides and oligosaccharides to release β-D-glucose. One of the important functions of plant β-glucosidase is deglucosylation of inactive glucosides of phytohormones to regulate levels of active hormones. Tuberonic acid is a jasmonate-related compound that shows tuber-inducing activity in the potato. We have identified two enzymes, OsTAGG1 and OsTAGG2, that have hydrolytic activity towards tuberonic acid β-D-glucoside in rice (Oryza sativa L.). The expression of OsTAGG2 is upregulated by wounding and by methyl jasmonate, suggesting that this isozyme is involved in responses to biotic stresses and wounding, but the physiological substrate of OsTAGG2 remains ambiguous. In this study, we produced recombinant OsTAGG2 in Pichia pastoris (rOsTAGG2P), and investigated its substrate specificity in detail. From 1 L of culture medium, 2.1 mg of purified recombinant enzyme was obtained by ammonium sulfate precipitation and Ni-chelating column chromatography. The specific activity of rOsTAGG2P (182 U/mg) was close to that of the native enzyme (171 U/mg), unlike recombinant OsTAGG2 produced in Escherichia coli, which had approximately 3-fold lower specific activity than the native enzyme. The optimum pH and temperature for rOsTAGG2P were pH 3.4 and 60 °C. After pH and heat treatments, the enzyme retained its original activity in a pH range of 3.4-9.8 and below 55 °C. Native OsTAGG2 and rOsTAGG2P showed 4.5-4.7-fold higher activities towards salicylic acid β-D-glucoside, an inactive storage-form of salicylic acid, than towards tuberonic acid β-D-glucoside (TAG), although OsTAGG2 was originally isolated from rice based on TAG-hydrolytic activity.

Published

2013

46. Elucidation of the biosynthetic pathway of cis-jasmone in Lasiodiplodia theobromae

Author

Wataru Saburi, Kazuhiko Matsuda, Hideyuki Matsuura, Naruki Amano, Ryo Matsui, Kosaku Takahashi, Yodai Taguchi, Norio Kondo, and Hideharu Mori

Subjects

0106 biological sciences, 0301 basic medicine, Science, Jasmone, Cyclopentanes, Cochliobolus heterostrophus, Acetates, 01 natural sciences, Article, Bioinorganic chemistry, 03 medical and health sciences, chemistry.chemical_compound, Ascomycota, Verticillium longisporum, Fusarium oxysporum, Oxylipins, Botrytis cinerea, Multidisciplinary, biology, Jasmonic acid, biology.organism_classification, Deuterium, Biosynthetic Pathways, 030104 developmental biology, chemistry, Biochemistry, Fatty Acids, Unsaturated, Metabolome, Gibberella fujikuroi, Medicine, Secondary metabolism, 010606 plant biology & botany, Lasiodiplodia theobromae

Abstract

In plants, cis-jasmone (CJ) is synthesized from α-linolenic acid (LA) via two biosynthetic pathways using jasmonic acid (JA) and iso-12-oxo-phytodienoic acid (iso-OPDA) as key intermediates. However, there have been no reports documenting CJ production by microorganisms. In the present study, the production of fungal-derived CJ by Lasiodiplodia theobromae was observed for the first time, although this production was not observed for Botrytis cinerea, Verticillium longisporum, Fusarium oxysporum, Gibberella fujikuroi, and Cochliobolus heterostrophus. To investigate the biosynthetic pathway of CJ in L. theobromae, administration experiments using [18,18,18-2H3, 17,17-2H2]LA (LA-d5), [18,18,18-2H3, 17,17-2H2]12-oxo-phytodienoic acid (cis-OPDA-d5), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 8:0 (OPC8-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 6:0 (OPC6-d6), [5′,5′,5′-2H3, 4′,4′-2H2, 3′-2H1]OPC 4:0 (OPC4-d6), and [11,11-2H2, 10,10-2H2, 8,8-2H2, 2,2-2H2]methyl iso-12-oxo-phytodienoate (iso-MeOPDA-d8) were carried out, revealing that the fungus produced CJ through a single biosynthetic pathway via iso-OPDA. Interestingly, it was suggested that the previously predicted decarboxylation step of 3,7-didehydroJA to afford CJ might not be involved in CJ biosynthesis in L. theobromae.

Published

2017

47. Identification and Characterization of Cellobiose 2-Epimerases from Various Aerobes

Author

Takeshi Yamamoto, Teruyo Ojima, Haruhide Mori, Hirokazu Matsui, and Wataru Saburi

Subjects

Cellobiose, Pedobacter heparinus, Lactose, medicine.disease_cause, Applied Microbiology and Biotechnology, Biochemistry, Substrate Specificity, Analytical Chemistry, chemistry.chemical_compound, Bacterial Proteins, Species Specificity, epimerization, Saccharophagus degradans, Enzyme Stability, epilactose, Escherichia coli, medicine, Molecular Biology, Phylogeny, Enzyme Assays, Thermostability, biology, Dyadobacter fermentans, Chemistry, Organic Chemistry, Temperature, Stereoisomerism, General Medicine, Hydrogen-Ion Concentration, cellobiose 2-epimerase, biology.organism_classification, Aerobiosis, Recombinant Proteins, Bacteria, Aerobic, Isoenzymes, Kinetics, Glucose, N-acetyl-D-glucosamine 2-epimerase, Carbohydrate Epimerases, Mannose, Bacteria, Biotechnology

Abstract

Cellobiose 2-epimerase (CE), found mainly in anaerobes, reversibly converts D-glucose residues at the reducing end of β-1,4-linked oligosaccharides to D-mannose residues. In this study, we characterized CE-like proteins from various aerobes (Flavobacterium johnsoniae NBRC 14942, Pedobacter heparinus NBRC 12017, Dyadobacter fermentans ATCC 700827, Herpetosiphon aurantiacus ATCC 23779, Saccharophagus degradans ATCC 43961, Spirosoma linguale ATCC 33905, and Teredinibacter turnerae ATCC 39867), because aerobes, more easily cultured on a large scale than anaerobes, are applicable in industrial processes. The recombinant CE-like proteins produced in Escherichia coli catalyzed epimerization at the C2 position of cellobiose, lactose, epilactose, and β-1,4-mannobiose, whereas N-acetyl-D-glucosamine, N-acetyl-D-mannosamine, D-glucose, and D-mannose were inert as substrates. All the CEs, except for P. heparinus CE, the optimum pH of which was 6.3, showed highest activity at weakly alkaline pH. CEs from D. fermentans, H. aurantiacus, and S. linguale showed higher optimum temperatures and thermostability than the other enzymes analyzed. The enzymes from D. fermentans, S. linguale, and T. turnerae showed significantly high k(cat) and K(m) values towards cellobiose and lactose. Especially, T. turnerae CE showed a very high k(cat) value towards lactose, an attractive property for the industrial production of epilactose, which is carried out at high substrate concentrations.

Published

2013

48. [Review: Symposium on Applied Glycoscience] Practical Enzymatic Production of Epilactose with Cellobiose 2-Epimerase

Author

Hidenori Taguchi, Hiroki Sato, Teruyo Ojima, Hirokazu Matsui, Haruhide Mori, and Wataru Saburi

Subjects

chemistry.chemical_classification, chemistry.chemical_compound, Enzyme, chemistry, Biochemistry, Epilactose, General Medicine, Cellobiose

Published

2013

49. Functions, structures, and applications of cellobiose 2-epimerase and glycoside hydrolase family 130 mannoside phosphorylases

Author

Wataru Saburi

Subjects

0301 basic medicine, Models, Molecular, Aldose-Ketose Isomerases, Cellobiose, Stereochemistry, Isomerase, Disaccharides, Applied Microbiology and Biotechnology, Biochemistry, β-1,4-mannooligosaccharide phosphorylase, Analytical Chemistry, Substrate Specificity, Bacteroides fragilis, 03 medical and health sciences, chemistry.chemical_compound, Cellvibrio, Catalytic Domain, Hydrolase, epilactose, Glycoside hydrolase, Amino Acid Sequence, Molecular Biology, Histidine, Phosphorolysis, 4-O-β-d-mannosyl-d-glucose phosphorylase, Organic Chemistry, beta-Mannosidase, General Medicine, Gene Expression Regulation, Bacterial, cellobiose 2-epimerase, Nucleotidyltransferases, Carbohydrate Epimerases, 030104 developmental biology, Glucose, chemistry, Carbohydrate Metabolism, glycoside hydrolase family 130, Protons, Mannose, Biotechnology

Abstract

Carbohydrate isomerases/epimerases are essential in carbohydrate metabolism, and have great potential in industrial carbohydrate conversion. Cellobiose 2-epimerase (CE) reversibly epimerizes the reducing end d-glucose residue of β-(1→4)-linked disaccharides to d-mannose residue. CE shares catalytic machinery with monosaccharide isomerases and epimerases having an (α/α)6-barrel catalytic domain. Two histidine residues act as general acid and base catalysts in the proton abstraction and addition mechanism. β-Mannoside hydrolase and 4-O-β-d-mannosyl-d-glucose phosphorylase (MGP) were found as neighboring genes of CE, meaning that CE is involved in β-mannan metabolism, where it epimerizes β-d-mannopyranosyl-(1→4)-d-mannose to β-d-mannopyranosyl-(1→4)-d-glucose for further phosphorolysis. MGPs form glycoside hydrolase family 130 (GH130) together with other β-mannoside phosphorylases and hydrolases. Structural analysis of GH130 enzymes revealed an unusual catalytic mechanism involving a proton relay and the molecular basis for substrate and reaction specificities. Epilactose, efficiently produced from lactose using CE, has superior physiological functions as a prebiotic oligosaccharide.

Published

2016

50. Metabolic Mechanism of Mannan in a Ruminal Bacterium, Ruminococcus albus, Involving Two Mannoside Phosphorylases and Cellobiose 2-Epimerase

Author

Hidenori Taguchi, Haruhide Mori, Shigeaki Ito, Rei Odaka, Ryosuke Kawahara, Hirokazu Matsui, and Wataru Saburi

Subjects

chemistry.chemical_classification, Cell Biology, Maltose, Cellobiose, Biology, Carbohydrate, Biochemistry, chemistry.chemical_compound, Glycogen phosphorylase, Metabolic pathway, Enzyme, chemistry, Molecular Biology, Phosphorolysis, Mannan

Abstract

Ruminococcus albus is a typical ruminal bacterium digesting cellulose and hemicellulose. Cellobiose 2-epimerase (CE; EC 5.1.3.11), which converts cellobiose to 4-O-β-d-glucosyl-d-mannose, is a particularly unique enzyme in R. albus, but its physiological function is unclear. Recently, a new metabolic pathway of mannan involving CE was postulated for another CE-producing bacterium, Bacteroides fragilis. In this pathway, β-1,4-mannobiose is epimerized to 4-O-β-d-mannosyl-d-glucose (Man-Glc) by CE, and Man-Glc is phosphorolyzed to α-d-mannosyl 1-phosphate (Man1P) and d-glucose by Man-Glc phosphorylase (MP; EC 2.4.1.281). Ruminococcus albus NE1 showed intracellular MP activity, and two MP isozymes, RaMP1 and RaMP2, were obtained from the cell-free extract. These enzymes were highly specific for the mannosyl residue at the non-reducing end of the substrate and catalyzed the phosphorolysis and synthesis of Man-Glc through a sequential Bi Bi mechanism. In a synthetic reaction, RaMP1 showed high activity only toward d-glucose and 6-deoxy-d-glucose in the presence of Man1P, whereas RaMP2 showed acceptor specificity significantly different from RaMP1. RaMP2 acted on d-glucose derivatives at the C2- and C3-positions, including deoxy- and deoxyfluoro-analogues and epimers, but not on those substituted at the C6-position. Furthermore, RaMP2 had high synthetic activity toward the following oligosaccharides: β-linked glucobioses, maltose, N,N′-diacetylchitobiose, and β-1,4-mannooligosaccharides. Particularly, β-1,4-mannooligosaccharides served as significantly better acceptor substrates for RaMP2 than d-glucose. In the phosphorolytic reactions, RaMP2 had weak activity toward β-1,4-mannobiose but efficiently degraded β-1,4-mannooligosaccharides longer than β-1,4-mannobiose. Consequently, RaMP2 is thought to catalyze the phosphorolysis of β-1,4-mannooligosaccharides longer than β-1,4-mannobiose to produce Man1P and β-1,4-mannobiose.

Published

2012