Your search keyword '"Glycoside Hydrolases metabolism"' showing total 484 results

1. The molecular basis of cereal mixed-linkage β-glucan utilization by the human gut bacterium Segatella copri.

Author

Golisch B, Cordeiro RL, Fraser ASC, Briggs J, Stewart WA, Van Petegem F, and Brumer H

Subjects

Humans, Prevotella metabolism, Prevotella genetics, Bacterial Proteins metabolism, Bacterial Proteins genetics, Glycoside Hydrolases metabolism, Glycoside Hydrolases genetics, beta-Glucans metabolism, Gastrointestinal Microbiome, Edible Grain metabolism, Edible Grain microbiology

Abstract

Mixed-linkage β(1,3)/β(1,4)-glucan (MLG) is abundant in the human diet through the ingestion of cereal grains and is widely associated with healthful effects on metabolism and cholesterol levels. MLG is also a major source of fermentable glucose for the human gut microbiota (HGM). Bacteria from the family Prevotellaceae are highly represented in the HGM of individuals who eat plant-rich diets, including certain indigenous people and vegetarians in postindustrial societies. Here, we have defined and functionally characterized an exemplar Prevotellaceae MLG polysaccharide utilization locus (MLG-PUL) in the type-strain Segatella copri (syn. Prevotella copri) DSM 18205 through transcriptomic, biochemical, and structural biological approaches. In particular, structure-function analysis of the cell-surface glycan-binding proteins and glycoside hydrolases of the S. copri MLG-PUL revealed the molecular basis for glycan capture and saccharification. Notably, syntenic MLG-PULs from human gut, human oral, and ruminant gut Prevotellaceae are distinguished from their counterparts in Bacteroidaceae by the presence of a β(1,3)-specific endo-glucanase from glycoside hydrolase family 5, subfamily 4 (GH5_4) that initiates MLG backbone cleavage. The definition of a family of homologous MLG-PULs in individual species enabled a survey of nearly 2000 human fecal microbiomes using these genes as molecular markers, which revealed global population-specific distributions of Bacteroidaceae- and Prevotellaceae-mediated MLG utilization. Altogether, the data presented here provide new insight into the molecular basis of β-glucan metabolism in the HGM, as a basis for informing the development of approaches to improve the nutrition and health of humans and other animals., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. The IgG-specific endoglycosidases EndoS and EndoS2 are distinguished by conformation and antibody recognition.

Author

Sudol ASL, Crispin M, and Tews I

Subjects

Humans, Crystallography, X-Ray, Immunoglobulin Fc Fragments chemistry, Immunoglobulin Fc Fragments metabolism, Substrate Specificity, Protein Structure, Quaternary, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Immunoglobulin G chemistry, Immunoglobulin G metabolism, Models, Molecular, Streptococcus pyogenes enzymology

Abstract

The IgG-specific endoglycosidases EndoS and EndoS2 from Streptococcus pyogenes can remove conserved N-linked glycans present on the Fc region of host antibodies to inhibit Fc-mediated effector functions. These enzymes are therefore being investigated as therapeutics for suppressing unwanted immune activation, and have additional application as tools for antibody glycan remodeling. EndoS and EndoS2 differ in Fc glycan substrate specificity due to structural differences within their catalytic glycosyl hydrolase domains. However, a chimeric EndoS enzyme with a substituted glycosyl hydrolase from EndoS2 loses catalytic activity, despite high structural homology between the two enzymes, indicating either mechanistic divergence of EndoS and EndoS2, or improperly-formed domain interfaces in the chimeric enzyme. Here, we present the crystal structure of the EndoS2-IgG1 Fc complex determined to 3.0 Å resolution. Comparison of complexed and unliganded EndoS2 reveals relative reorientation of the glycosyl hydrolase, leucine-rich repeat and hybrid immunoglobulin domains. The conformation of the complexed EndoS2 enzyme is also different when compared to the earlier EndoS-IgG1 Fc complex, and results in distinct contact surfaces between the two enzymes and their Fc substrate. These findings indicate mechanistic divergence of EndoS2 and EndoS. It will be important to consider these differences in the design of IgG-specific enzymes, developed to enable customizable antibody glycosylation., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

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

Author

Ota T, Saburi W, Tagami T, Yu J, Komba S, Jewell LE, Hsiang T, Imai R, Yao M, and Mori H

Subjects

Glucans metabolism, Glucose, Glucosidases metabolism, Substrate Specificity, beta-Glucans, Glycoside Hydrolases metabolism

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 k cat /K m 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., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

4. O-GlcNAc has crosstalk with ADP-ribosylation via PARG.

Author

Li J, Liu X, Peng B, Feng T, Zhou W, Meng L, Zhao S, Zheng X, Wu C, Wu S, Chen X, Xu X, Sun J, and Li J

Subjects

Animals, Humans, Mice, Acetylglucosamine, ADP-Ribosylation, Poly Adenosine Diphosphate Ribose metabolism, Glycosylation, Protein Processing, Post-Translational, Carcinoma, Hepatocellular, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Liver Neoplasms

Abstract

O-linked N-acetylglucosamine (O-GlcNAc) glycosylation, a prevalent protein post-translational modification (PTM) that occurs intracellularly, has been shown to crosstalk with phosphorylation and ubiquitination. However, it is unclear whether it interplays with other PTMs. Here we studied its relationship with ADP-ribosylation, which involves decorating target proteins with the ADP-ribose moiety. We discovered that the poly(ADP-ribosyl)ation "eraser", ADP-ribose glycohydrolase (PARG), is O-GlcNAcylated at Ser26, which is in close proximity to its nuclear localization signal. O-GlcNAcylation of PARG promotes nuclear localization and chromatin association. Upon DNA damage, O-GlcNAcylation augments the recruitment of PARG to DNA damage sites and interacting with proliferating cell nuclear antigen (PCNA). In hepatocellular carcinoma (HCC) cells, PARG O-GlcNAcylation enhances the poly(ADP-ribosyl)ation of DNA damage-binding protein 1 (DDB1) and attenuates its auto-ubiquitination, thereby stabilizing DDB1 and allowing it to degrade its downstream targets, such as c-Myc. We further demonstrated that PARG-S26A, the O-GlcNAc-deficient mutant, promoted HCC in mouse xenograft models. Our findings thus reveal that PARG O-GlcNAcylation inhibits HCC, and we propose that O-GlcNAc glycosylation may crosstalk with many other PTMs., Competing Interests: Conflicts of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

5. PARP14 is a writer, reader, and eraser of mono-ADP-ribosylation.

Author

Torretta A, Chatzicharalampous C, Ebenwaldner C, and Schüler H

Subjects

Humans, Glycoside Hydrolases metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Poly Adenosine Diphosphate Ribose metabolism, Adenosine Diphosphate Ribose metabolism, Neoplasm Proteins, ADP-Ribosylation, Poly(ADP-ribose) Polymerases metabolism, Poly(ADP-ribose) Polymerases chemistry, Poly(ADP-ribose) Polymerases genetics, Protein Domains

Abstract

PARP14/BAL2 is a large multidomain enzyme involved in signaling pathways with relevance to cancer, inflammation, and infection. Inhibition of its mono-ADP-ribosylating PARP homology domain and its three ADP-ribosyl binding macro domains has been regarded as a potential means of therapeutic intervention. Macrodomains-2 and -3 are known to stably bind to ADP-ribosylated target proteins, but the function of macrodomain-1 has remained somewhat elusive. Here, we used biochemical assays of ADP-ribosylation levels to characterize PARP14 macrodomain-1 and the homologous macrodomain-1 of PARP9. Our results show that both macrodomains display an ADP-ribosyl glycohydrolase activity that is not directed toward specific protein side chains. PARP14 macrodomain-1 is unable to degrade poly(ADP-ribose), the enzymatic product of PARP1. The F926A mutation of PARP14 and the F244A mutation of PARP9 strongly reduced ADP-ribosyl glycohydrolase activity of the respective macrodomains, suggesting mechanistic homology to the Mac1 domain of the SARS-CoV-2 Nsp3 protein. This study adds two new enzymes to the previously known six human ADP-ribosyl glycohydrolases. Our results have key implications for how PARP14 and PARP9 will be studied and how their functions will be understood., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

6. Bacteroidota polysaccharide utilization system for branched dextran exopolysaccharides from lactic acid bacteria.

Author

Nakamura S, Kurata R, Tonozuka T, Funane K, Park EY, and Miyazaki T

Subjects

Glucans metabolism, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Dextrans metabolism, Lactobacillales metabolism, Flavobacterium metabolism, Polysaccharides, Bacterial metabolism

Abstract

Dextran is an α-(1→6)-glucan that is synthesized by some lactic acid bacteria, and branched dextran with α-(1→2)-, α-(1→3)-, and α-(1→4)-linkages are often produced. Although many dextranases are known to act on the α-(1→6)-linkage of dextran, few studies have functionally analyzed the proteins involved in degrading branched dextran. The mechanism by which bacteria utilize branched dextran is unknown. Earlier, we identified dextranase (FjDex31A) and kojibiose hydrolase (FjGH65A) in the dextran utilization locus (FjDexUL) of a soil Bacteroidota Flavobacterium johnsoniae and hypothesized that FjDexUL is involved in the degradation of α-(1→2)-branched dextran. In this study, we demonstrate that FjDexUL proteins recognize and degrade α-(1→2)- and α-(1→3)-branched dextrans produced by Leuconostoc citreum S-32 (S-32 α-glucan). The FjDexUL genes were significantly upregulated when S-32 α-glucan was the carbon source compared with α-glucooligosaccharides and α-glucans, such as linear dextran and branched α-glucan from L. citreum S-64. FjDexUL glycoside hydrolases synergistically degraded S-32 α-glucan. The crystal structure of FjGH66 shows that some sugar-binding subsites can accommodate α-(1→2)- and α-(1→3)-branches. The structure of FjGH65A in complex with isomaltose supports that FjGH65A acts on α-(1→2)-glucosyl isomaltooligosaccharides. Furthermore, two cell surface sugar-binding proteins (FjDusD and FjDusE) were characterized, and FjDusD showed an affinity for isomaltooligosaccharides and FjDusE for dextran, including linear and branched dextrans. Collectively, FjDexUL proteins are suggested to be involved in the degradation of α-(1→2)- and α-(1→3)-branched dextrans. Our results will be helpful in understanding the bacterial nutrient requirements and symbiotic relationships between bacteria at the molecular level., Competing Interests: Conflicts of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

7. A subfamily classification to choreograph the diverse activities within glycoside hydrolase family 31.

Author

Arumapperuma T, Li J, Hornung B, Soler NM, Goddard-Borger ED, Terrapon N, and Williams SJ

Subjects

Phylogeny, Polysaccharides metabolism, Proteins, Substrate Specificity, Betaproteobacteria enzymology, Multigene Family, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism

Abstract

The Carbohydrate-Active Enzyme classification groups enzymes that breakdown, assemble, or decorate glycans into protein families based on sequence similarity. The glycoside hydrolases (GH) are arranged into over 170 enzyme families, with some being very large and exhibiting distinct activities/specificities towards diverse substrates. Family GH31 is a large family that contains more than 20,000 sequences with a wide taxonomic diversity. Less than 1% of GH31 members are biochemically characterized and exhibit many different activities that include glycosidases, lyases, and transglycosidases. This diversity of activities limits our ability to predict the activities and roles of GH31 family members in their host organism and our ability to exploit these enzymes for practical purposes. Here, we established a subfamily classification using sequence similarity networks that was further validated by a structural analysis. While sequence similarity networks provide a sequence-based separation, we obtained good segregation between activities among the subfamilies. Our subclassification consists of 20 subfamilies with sixteen subfamilies containing at least one characterized member and eleven subfamilies that are monofunctional based on the available data. We also report the biochemical characterization of a member of the large subfamily 2 (GH31_2) that lacked any characterized members: RaGH31 from Rhodoferax aquaticus is an α-glucosidase with activity on a range of disaccharides including sucrose, trehalose, maltose, and nigerose. Our subclassification provides improved predictive power for the vast majority of uncharacterized proteins in family GH31 and highlights the remaining sequence space that remains to be functionally explored., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

8. Unusual β1-4-galactosidase activity of an α1-6-mannosidase from Xanthomonas manihotis in the processing of branched hybrid and complex glycans.

Author

She YM, Klupt K, Hatfield G, Jia Z, and Tam RY

Subjects

Galactose metabolism, Glycoproteins metabolism, Glycoside Hydrolases metabolism, Mannose, Mannosides metabolism, Oligosaccharides metabolism, Polysaccharides metabolism, Xanthomonas enzymology, alpha-Mannosidase metabolism, beta-Galactosidase metabolism

Abstract

Mannosidases are a diverse group of glycoside hydrolases that play crucial roles in mannose trimming of oligomannose glycans, glycoconjugates, and glycoproteins involved in numerous cellular processes, such as glycan biosynthesis and metabolism, structure regulation, cellular recognition, and cell-pathogen interactions. Exomannosidases and endomannosidases cleave specific glycosidic bonds of mannoside linkages in glycans and can be used in enzyme-based methods for sequencing of isomeric glycan structures. α1-6-mannosidase from Xanthomonas manihotis is known as a highly specific exoglycosidase that removes unbranched α1-6 linked mannose residues from oligosaccharides. However, we discovered that this α1-6-mannosidase also possesses an unexpected β1-4-galactosidase activity in the processing of branched hybrid and complex glycans through our use of enzymatic reactions, high performance anion-exchange chromatography, and liquid chromatography mass spectrometric sequencing. Our docking simulation of the α1-6-mannosidase with glycan substrates reveals potential interacting residues in a relatively shallow pocket slightly differing from its homologous enzymes in the glycoside hydrolase 125 family, which may be responsible for the observed higher promiscuity in substrate binding and subsequent terminal glycan hydrolysis. This observation of novel β1-4-galactosidase activity of the α1-6-mannosidase provides unique insights into its bifunctional activity on the substrate structure-dependent processing of terminal α1-6-mannose of unbranched glycans and terminal β1-4-galactose of hybrid and complex glycans. The finding thus suggests the dual glycosidase specificity of this α1-6-mannosidase and the need for careful consideration when used for the structural elucidation of glycan isomers., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Crown Copyright © 2022. Published by Elsevier Inc. All rights reserved.)

Published

2022

9. Structural basis of the strict specificity of a bacterial GH31 α-1,3-glucosidase for nigerooligosaccharides.

Author

Ikegaya M, Moriya T, Adachi N, Kawasaki M, Park EY, and Miyazaki T

Subjects

Amino Acid Sequence, Bacteria metabolism, Cryoelectron Microscopy, Crystallography, X-Ray, Fungi metabolism, Lactococcus lactis enzymology, Lactococcus lactis metabolism, Models, Molecular, Oligosaccharides metabolism, Phylogeny, Substrate Specificity, Bacteria enzymology, Fungi enzymology, Glucosidases metabolism, Glycoside Hydrolases metabolism

Abstract

Carbohydrate-active enzymes are involved in the degradation, biosynthesis, and modification of carbohydrates and vary with the diversity of carbohydrates. The glycoside hydrolase (GH) family 31 is one of the most diverse families of carbohydrate-active enzymes, containing various enzymes that act on α-glycosides. However, the function of some GH31 groups remains unknown, as their enzymatic activity is difficult to estimate due to the low amino acid sequence similarity between characterized and uncharacterized members. Here, we performed a phylogenetic analysis and discovered a protein cluster (GH31_u1) sharing low sequence similarity with the reported GH31 enzymes. Within this cluster, we showed that a GH31_u1 protein from Lactococcus lactis (LlGH31_u1) and its fungal homolog demonstrated hydrolytic activities against nigerose [α-D-Glcp-(1→3)-D-Glc]. The k cat /K m values of LlGH31_u1 against kojibiose and maltose were 13% and 2.1% of that against nigerose, indicating that LlGH31_u1 has a higher specificity to the α-1,3 linkage of nigerose than other characterized GH31 enzymes, including eukaryotic enzymes. Furthermore, the three-dimensional structures of LlGH31_u1 determined using X-ray crystallography and cryogenic electron microscopy revealed that LlGH31_u1 forms a hexamer and has a C-terminal domain comprising four α-helices, suggesting that it contributes to hexamerization. Finally, crystal structures in complex with nigerooligosaccharides and kojibiose along with mutational analysis revealed the active site residues involved in substrate recognition in this enzyme. This study reports the first structure of a bacterial GH31 α-1,3-glucosidase and provides new insight into the substrate specificity of GH31 enzymes and the physiological functions of bacterial and fungal GH31_u1 members., Competing Interests: Conflict of interest The authors have no conflicts of interest to declare., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

10. Characterization and structural analyses of a novel glycosyltransferase acting on the β-1,2-glucosidic linkages.

Author

Kobayashi K, Shimizu H, Tanaka N, Kuramochi K, Nakai H, Nakajima M, and Taguchi H

Subjects

Glucosyltransferases metabolism, Glycoside Hydrolases metabolism, Kinetics, Substrate Specificity, Glucosides chemistry, Glucosides metabolism, Glycosyltransferases chemistry, Glycosyltransferases metabolism

Abstract

The IALB_1185 protein, which is encoded in the gene cluster for endo-β-1,2-glucanase homologs in the genome of Ignavibacterium album, is a glycoside hydrolase family (GH) 35 protein. However, most known GH35 enzymes are β-galactosidases, which is inconsistent with the components of this gene cluster. Thus, IALB_1185 is expected to possess novel enzymatic properties. Here, we showed using recombinant IALB_1185 that this protein has glycosyltransferase activity toward β-1,2-glucooligosaccharides, and that the kinetic parameters for β-1,2-glucooligosaccharides are not within the ranges for general GH enzymes. When various aryl- and alkyl-glucosides were used as acceptors, glycosyltransfer products derived from these acceptors were subsequently detected. Kinetic analysis further revealed that the enzyme has wide aglycone specificity regardless of the anomer, and that the β-1,2-linked glucose dimer sophorose is an appropriate donor. In the complex of wild-type IALB_1185 with sophorose, the electron density of sophorose was clearly observed at subsites -1 and +1, whereas in the E343Q mutant-sophorose complex, the electron density of sophorose was clearly observed at subsites +1 and +2. This observation suggests that binding at subsites -1 and +2 competes through Glu102, which is consistent with the preference for sophorose as a donor and unsuitability of β-1,2-glucooligosaccharides as acceptors. A pliable hydrophobic pocket that can accommodate various aglycone moieties was also observed in the complex structures with various glucosides. Overall, our biochemical and structural data are indicative of a novel enzymatic reaction. We propose that IALB_1185 be redefined β-1,2-glucooligosaccharide:d-glucoside β-d-glucosyltransferase as a systematic name and β-1,2-glucosyltransferase as an accepted name., Competing Interests: Conflict of interest The authors declare that there is no conflict of interest with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

11. Comparison of glycoside hydrolase family 3 β-xylosidases from basidiomycetes and ascomycetes reveals evolutionarily distinct xylan degradation systems.

Author

Kojima K, Sunagawa N, Mikkelsen NE, Hansson H, Karkehabadi S, Samejima M, Sandgren M, and Igarashi K

Subjects

Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Phylogeny, Substrate Specificity, Ascomycota enzymology, Ascomycota genetics, Phanerochaete enzymology, Phanerochaete genetics, Xylans metabolism, Xylosidases chemistry, Xylosidases genetics, Xylosidases metabolism

Abstract

Xylan is the most common hemicellulose in plant cell walls, though the structure of xylan polymers differs between plant species. Here, to gain a better understanding of fungal xylan degradation systems, which can enhance enzymatic saccharification of plant cell walls in industrial processes, we conducted a comparative study of two glycoside hydrolase family 3 (GH3) β-xylosidases (Bxls), one from the basidiomycete Phanerochaete chrysosporium (PcBxl3), and the other from the ascomycete Trichoderma reesei (TrXyl3A). A comparison of the crystal structures of the two enzymes, both with saccharide bound at the catalytic center, provided insight into the basis of substrate binding at each subsite. PcBxl3 has a substrate-binding pocket at subsite -1, while TrXyl3A has an extra loop that contains additional binding subsites. Furthermore, kinetic experiments revealed that PcBxl3 degraded xylooligosaccharides faster than TrXyl3A, while the K M values of TrXyl3A were lower than those of PcBxl3. The relationship between substrate specificity and degree of polymerization of substrates suggested that PcBxl3 preferentially degrades xylobiose (X 2 ), while TrXyl3A degrades longer xylooligosaccharides. Moreover, docking simulation supported the existence of extended positive subsites of TrXyl3A in the extra loop located at the N-terminus of the protein. Finally, phylogenetic analysis suggests that wood-decaying basidiomycetes use Bxls such as PcBxl3 that act efficiently on xylan structures from woody plants, whereas molds use instead Bxls that efficiently degrade xylan from grass. Our results provide added insights into fungal efficient xylan degradation systems., Competing Interests: Conflict of interest The authors declare that there is no conflict of interests with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

12. Structure of a bacterial α-1,2-glucosidase defines mechanisms of hydrolysis and substrate specificity in GH65 family hydrolases.

Author

Nakamura S, Nihira T, Kurata R, Nakai H, Funane K, Park EY, and Miyazaki T

Subjects

Amino Acid Sequence, Catalysis, Catalytic Domain, Crystallography, X-Ray, Hydrolysis, Protein Conformation, Sequence Homology, Amino Acid, Substrate Specificity, Flavobacterium enzymology, Glycoside Hydrolases metabolism, alpha-Glucosidases chemistry, alpha-Glucosidases metabolism

Abstract

Glycoside hydrolase family 65 (GH65) comprises glycoside hydrolases (GHs) and glycoside phosphorylases (GPs) that act on α-glucosidic linkages in oligosaccharides. All previously reported bacterial GH65 enzymes are GPs, whereas all eukaryotic GH65 enzymes known are GHs. In addition, to date, no crystal structure of a GH65 GH has yet been reported. In this study, we use biochemical experiments and X-ray crystallography to examine the function and structure of a GH65 enzyme from Flavobacterium johnsoniae (FjGH65A) that shows low amino acid sequence homology to reported GH65 enzymes. We found that FjGH65A does not exhibit phosphorolytic activity, but it does hydrolyze kojibiose (α-1,2-glucobiose) and oligosaccharides containing a kojibiosyl moiety without requiring inorganic phosphate. In addition, stereochemical analysis demonstrated that FjGH65A catalyzes this hydrolytic reaction via an anomer-inverting mechanism. The three-dimensional structures of FjGH65A in native form and in complex with glucose were determined at resolutions of 1.54 and 1.40 Å resolutions, respectively. The overall structure of FjGH65A resembled those of other GH65 GPs, and the general acid catalyst Glu 472 was conserved. However, the amino acid sequence forming the phosphate-binding site typical of GH65 GPs was not conserved in FjGH65A. Moreover, FjGH65A had the general base catalyst Glu 616 instead, which is required to activate a nucleophilic water molecule. These results indicate that FjGH65A is an α-1,2-glucosidase and is the first bacterial GH found in the GH65 family., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

13. Machine learning reveals sequence-function relationships in family 7 glycoside hydrolases.

Author

Gado JE, Harrison BE, Sandgren M, Ståhlberg J, Beckham GT, and Payne CM

Subjects

Machine Learning, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Glycoside Hydrolases genetics, Catalytic Domain

Abstract

Family 7 glycoside hydrolases (GH7) are among the principal enzymes for cellulose degradation in nature and industrially. These enzymes are often bimodular, including a catalytic domain and carbohydrate-binding module (CBM) attached via a flexible linker, and exhibit an active site that binds cello-oligomers of up to ten glucosyl moieties. GH7 cellulases consist of two major subtypes: cellobiohydrolases (CBH) and endoglucanases (EG). Despite the critical importance of GH7 enzymes, there remain gaps in our understanding of how GH7 sequence and structure relate to function. Here, we employed machine learning to gain data-driven insights into relationships between sequence, structure, and function across the GH7 family. Machine-learning models, trained only on the number of residues in the active-site loops as features, were able to discriminate GH7 CBHs and EGs with up to 99% accuracy, demonstrating that the lengths of loops A4, B2, B3, and B4 strongly correlate with functional subtype across the GH7 family. Classification rules were derived such that specific residues at 42 different sequence positions each predicted the functional subtype with accuracies surpassing 87%. A random forest model trained on residues at 19 positions in the catalytic domain predicted the presence of a CBM with 89.5% accuracy. Our machine learning results recapitulate, as top-performing features, a substantial number of the sequence positions determined by previous experimental studies to play vital roles in GH7 activity. We surmise that the yet-to-be-explored sequence positions among the top-performing features also contribute to GH7 functional variation and may be exploited to understand and manipulate function., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Published by Elsevier Inc.)

Published

2021

14. Anionic amino acids support hydrolysis of poly-β-(1,6)-N-acetylglucosamine exopolysaccharides by the biofilm dispersing glycosidase Dispersin B.

Author

Breslawec AP, Wang S, Li C, and Poulin MB

Subjects

Biofilms, Hydrolysis, Models, Molecular, Aggregatibacter actinomycetemcomitans metabolism, Amino Acids metabolism, Bacterial Proteins metabolism, Glycoside Hydrolases metabolism, beta-Glucans metabolism

Abstract

The exopolysaccharide poly-β-(1→6)-N-acetylglucosamine (PNAG) is a major structural determinant of bacterial biofilms responsible for persistent and nosocomial infections. The enzymatic dispersal of biofilms by PNAG-hydrolyzing glycosidase enzymes, such as Dispersin B (DspB), is a possible approach to treat biofilm-dependent bacterial infections. The cationic charge resulting from partial de-N-acetylation of native PNAG is critical for PNAG-dependent biofilm formation. We recently demonstrated that DspB has increased catalytic activity on de-N-acetylated PNAG oligosaccharides, but the molecular basis for this increased activity is not known. Here, we analyze the role of anionic amino acids surrounding the catalytic pocket of DspB in PNAG substrate recognition and hydrolysis using a combination of site-directed mutagenesis, activity measurements using synthetic PNAG oligosaccharide analogs, and in vitro biofilm dispersal assays. The results of these studies support a model in which bound PNAG is weakly associated with a shallow anionic groove on the DspB protein surface with recognition driven by interactions with the -1 GlcNAc residue in the catalytic pocket. An increased rate of hydrolysis for cationic PNAG was driven, in part, by interaction with D147 on the anionic surface. Moreover, we identified that a DspB mutant with improved hydrolysis of fully acetylated PNAG oligosaccharides correlates with improved in vitro dispersal of PNAG-dependent Staphylococcus epidermidis biofilms. These results provide insight into the mechanism of substrate recognition by DspB and suggest a method to improve DspB biofilm dispersal activity by mutation of the amino acids within the anionic binding surface., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

15. Distinct protein architectures mediate species-specific beta-glucan binding and metabolism in the human gut microbiota.

Author

Tamura K, Dejean G, Van Petegem F, and Brumer H

Subjects

Bacterial Proteins metabolism, Bacteroides metabolism, Bacteroides thetaiotaomicron metabolism, Gastrointestinal Microbiome genetics, Gastrointestinal Tract metabolism, Glucans metabolism, Glycoside Hydrolases metabolism, Humans, Membrane Proteins metabolism, Polysaccharides metabolism, Species Specificity, Gastrointestinal Microbiome physiology, beta-Glucans metabolism

Abstract

Complex glycans that evade our digestive system are major nutrients that feed the human gut microbiota (HGM). The prevalence of Bacteroidetes in the HGM of populations worldwide is engendered by the evolution of polysaccharide utilization loci (PULs), which encode concerted protein systems to utilize the myriad complex glycans in our diets. Despite their crucial roles in glycan recognition and transport, cell-surface glycan-binding proteins (SGBPs) remained understudied cogs in the PUL machinery. Here, we report the structural and biochemical characterization of a suite of SGBP-A and SGBP-B structures from three syntenic β(1,3)-glucan utilization loci (1,3GULs) from Bacteroides thetaiotaomicron (Bt), Bacteroides uniformis (Bu), and B. fluxus (Bf), which have varying specificities for distinct β-glucans. Ligand complexes provide definitive insight into β(1,3)-glucan selectivity in the HGM, including structural features enabling dual β(1,3)-glucan/mixed-linkage β(1,3)/β(1,4)-glucan-binding capability in some orthologs. The tertiary structural conservation of SusD-like SGBPs-A is juxtaposed with the diverse architectures and binding modes of the SGBPs-B. Specifically, the structures of the trimodular BtSGBP-B and BuSGBP-B revealed a tandem repeat of carbohydrate-binding module-like domains connected by long linkers. In contrast, BfSGBP-B comprises a bimodular architecture with a distinct β-barrel domain at the C terminus that bears a shallow binding canyon. The molecular insights obtained here contribute to our fundamental understanding of HGM function, which in turn may inform tailored microbial intervention therapies., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

16. The exo-β-N-acetylmuramidase NamZ from Bacillus subtilis is the founding member of a family of exo-lytic peptidoglycan hexosaminidases.

Author

Müller M, Calvert M, Hottmann I, Kluj RM, Teufel T, Balbuchta K, Engelbrecht A, Selim KA, Xu Q, Borisova M, Titz A, and Mayer C

Subjects

Crystallography, X-Ray, Glycoside Hydrolases chemistry, Hydrolysis, Protein Conformation, Acetylglucosamine metabolism, Bacillus subtilis enzymology, Glycoside Hydrolases metabolism, Muramic Acids metabolism, Peptidoglycan metabolism

Abstract

Endo-β-N-acetylmuramidases, commonly known as lysozymes, are well-characterized antimicrobial enzymes that catalyze an endo-lytic cleavage of peptidoglycan; i.e., they hydrolyze the β-1,4-glycosidic bonds connecting N-acetylmuramic acid (MurNAc) and N-acetylglucosamine (GlcNAc). In contrast, little is known about exo-β-N-acetylmuramidases, which catalyze an exo-lytic cleavage of β-1,4-MurNAc entities from the non-reducing ends of peptidoglycan chains. Such an enzyme was identified earlier in the bacterium Bacillus subtilis, but the corresponding gene has remained unknown so far. We now report that ybbC of B. subtilis, renamed namZ, encodes the reported exo-β-N-acetylmuramidase. A ΔnamZ mutant accumulated specific cell wall fragments and showed growth defects under starvation conditions, indicating a role of NamZ in cell wall turnover and recycling. Recombinant NamZ protein specifically hydrolyzed the artificial substrate para-nitrophenyl β-MurNAc and the peptidoglycan-derived disaccharide MurNAc-β-1,4-GlcNAc. Together with the exo-β-N-acetylglucosaminidase NagZ and the exo-muramoyl-l-alanine amidase AmiE, NamZ degraded intact peptidoglycan by sequential hydrolysis from the non-reducing ends. A structure model of NamZ, built on the basis of two crystal structures of putative orthologs from Bacteroides fragilis, revealed a two-domain structure including a Rossmann-fold-like domain that constitutes a unique glycosidase fold. Thus, NamZ, a member of the DUF1343 protein family of unknown function, is now classified as the founding member of a new family of glycosidases (CAZy GH171; www.cazy.org/GH171.html). NamZ-like peptidoglycan hexosaminidases are mainly present in the phylum Bacteroidetes and less frequently found in individual genomes within Firmicutes (Bacilli, Clostridia), Actinobacteria, and γ-proteobacteria., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the content of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

17. Structural and biochemical analysis of human ADP-ribosyl-acceptor hydrolase 3 reveals the basis of metal selectivity and different roles for the two magnesium ions.

Author

Pourfarjam Y, Ma Z, Kurinov I, Moss J, and Kim IK

Subjects

DNA Damage, Humans, Hydrolysis, Models, Molecular, Poly Adenosine Diphosphate Ribose metabolism, Protein Conformation, Substrate Specificity, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Magnesium metabolism

Abstract

ADP-ribosylation is a reversible and site-specific post-translational modification that regulates a wide array of cellular signaling pathways. Regulation of ADP-ribosylation is vital for maintaining genomic integrity, and uncontrolled accumulation of poly(ADP-ribosyl)ation triggers a poly(ADP-ribose) (PAR)-dependent release of apoptosis-inducing factor from mitochondria, leading to cell death. ADP-ribosyl-acceptor hydrolase 3 (ARH3) cleaves PAR and mono(ADP-ribosyl)ation at serine following DNA damage. ARH3 is also a metalloenzyme with strong metal selectivity. While coordination of two magnesium ions (Mg A and Mg B ) significantly enhances its catalytic efficiency, calcium binding suppresses its function. However, how the coordination of different metal ions affects its catalysis has not been defined. Here, we report a new crystal structure of ARH3 complexed with its product ADP-ribose and calcium. This structure shows that calcium coordination significantly distorts the binuclear metal center of ARH3, which results in decreased binding affinity to ADP-ribose, and suboptimal substrate alignment, leading to impaired hydrolysis of PAR and mono(ADP-ribosyl)ated serines. Furthermore, combined structural and mutational analysis of the metal-coordinating acidic residues revealed that Mg A is crucial for optimal substrate positioning for catalysis, whereas Mg B plays a key role in substrate binding. Our collective data provide novel insights into the different roles of these metal ions and the basis of metal selectivity of ARH3 and contribute to understanding the dynamic regulation of cellular ADP-ribosylations during the DNA damage response., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

18. Pantoea stewartii WceF is a glycan biofilm-modifying enzyme with a bacteriophage tailspike-like fold.

Author

Irmscher T, Roske Y, Gayk I, Dunsing V, Chiantia S, Heinemann U, and Barbirz S

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Bacteriophages chemistry, Bacteriophages enzymology, Binding Sites, Carbohydrate Sequence, Cloning, Molecular, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Genetic Vectors chemistry, Genetic Vectors metabolism, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Models, Molecular, Oligosaccharides chemistry, Oligosaccharides metabolism, Pantoea genetics, Plants microbiology, Polysaccharides, Bacterial metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Multimerization, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Structural Homology, Protein, Viral Tail Proteins genetics, Viral Tail Proteins metabolism, Bacterial Proteins chemistry, Biofilms growth & development, Glycoside Hydrolases chemistry, Pantoea enzymology, Polysaccharides, Bacterial chemistry, Viral Tail Proteins chemistry

Abstract

Pathogenic microorganisms often reside in glycan-based biofilms. Concentration and chain length distribution of these mostly anionic exopolysaccharides (EPS) determine the overall biophysical properties of a biofilm and result in a highly viscous environment. Bacterial communities regulate this biofilm state via intracellular small-molecule signaling to initiate EPS synthesis. Reorganization or degradation of this glycan matrix, however, requires the action of extracellular glycosidases. So far, these were mainly described for bacteriophages that must degrade biofilms for gaining access to host bacteria. The plant pathogen Pantoea stewartii (P. stewartii) encodes the protein WceF within its EPS synthesis cluster. WceF has homologs in various biofilm forming plant pathogens of the Erwinia family. In this work, we show that WceF is a glycosidase active on stewartan, the main P. stewartii EPS biofilm component. WceF has remarkable structural similarity with bacteriophage tailspike proteins (TSPs). Crystal structure analysis showed a native trimer of right-handed parallel β-helices. Despite its similar fold, WceF lacks the high stability found in bacteriophage TSPs. WceF is a stewartan hydrolase and produces oligosaccharides, corresponding to single stewartan repeat units. However, compared with a stewartan-specific glycan hydrolase of bacteriophage origin, WceF showed lectin-like autoagglutination with stewartan, resulting in notably slower EPS cleavage velocities. This emphasizes that the bacterial enzyme WceF has a role in P. stewartii biofilm glycan matrix reorganization clearly different from that of a bacteriophage exopolysaccharide depolymerase., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

19. The structure of a family 110 glycoside hydrolase provides insight into the hydrolysis of α-1,3-galactosidic linkages in λ-carrageenan and blood group antigens.

Author

McGuire BE, Hettle AG, Vickers C, King DT, Vocadlo DJ, and Boraston AB

Subjects

Blood Group Antigens chemistry, Carrageenan chemistry, Catalytic Domain, Crystallography, X-Ray, Galactosides chemistry, Glycoside Hydrolases classification, Glycoside Hydrolases metabolism, Hydrolysis, Models, Molecular, Phylogeny, Protein Conformation, Substrate Specificity, Blood Group Antigens metabolism, Carrageenan metabolism, Galactosides metabolism, Glycoside Hydrolases chemistry, Pseudoalteromonas enzymology

Abstract

α-Linked galactose is a common carbohydrate motif in nature that is processed by a variety of glycoside hydrolases from different families. Terminal Galα1-3Gal motifs are found as a defining feature of different blood group and tissue antigens, as well as the building block of the marine algal galactan λ-carrageenan. The blood group B antigen and linear α-Gal epitope can be processed by glycoside hydrolases in family GH110, whereas the presence of genes encoding GH110 enzymes in polysaccharide utilization loci from marine bacteria suggests a role in processing λ-carrageenan. However, the structure-function relationships underpinning the α-1,3-galactosidase activity within family GH110 remain unknown. Here we focus on a GH110 enzyme (PdGH110B) from the carrageenolytic marine bacterium Pseudoalteromonas distincta U2A. We showed that the enzyme was active on Galα1-3Gal but not the blood group B antigen. X-ray crystal structures in complex with galactose and unhydrolyzed Galα1-3Gal revealed the parallel β-helix fold of the enzyme and the structural basis of its inverting catalytic mechanism. Moreover, an examination of the active site reveals likely adaptations that allow accommodation of fucose in blood group B active GH110 enzymes or, in the case of PdGH110, accommodation of the sulfate groups found on λ-carrageenan. Overall, this work provides insight into the first member of a predominantly marine clade of GH110 enzymes while also illuminating the structural basis of α-1,3-galactoside processing by the family as a whole., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 McGuire et al.)

Published

2020

20. Unique active-site and subsite features in the arabinogalactan-degrading GH43 exo-β-1,3-galactanase from Phanerochaete chrysosporium .

Author

Matsuyama K, Kishine N, Fujimoto Z, Sunagawa N, Kotake T, Tsumuraya Y, Samejima M, Igarashi K, and Kaneko S

Subjects

Amino Acid Sequence, Catalytic Domain, Crystallography, X-Ray, Galactose analogs & derivatives, Sequence Homology, Substrate Specificity, Fungal Proteins chemistry, Fungal Proteins metabolism, Galactans metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Mannans metabolism, Phanerochaete enzymology

Abstract

Arabinogalactan proteins (AGPs) are plant proteoglycans with functions in growth and development. However, these functions are largely unexplored, mainly because of the complexity of the sugar moieties. These carbohydrate sequences are generally analyzed with the aid of glycoside hydrolases. The exo-β-1,3-galactanase is a glycoside hydrolase from the basidiomycete Phanerochaete chrysosporium ( Pc 1,3Gal43A), which specifically cleaves AGPs. However, its structure is not known in relation to its mechanism bypassing side chains. In this study, we solved the apo and liganded structures of Pc 1,3Gal43A, which reveal a glycoside hydrolase family 43 subfamily 24 (GH43_sub24) catalytic domain together with a carbohydrate-binding module family 35 (CBM35) binding domain. GH43_sub24 is known to lack the catalytic base Asp conserved among other GH43 subfamilies. Our structure in combination with kinetic analyses reveals that the tautomerized imidic acid group of Gln 263 serves as the catalytic base residue instead. Pc 1,3Gal43A has three subsites that continue from the bottom of the catalytic pocket to the solvent. Subsite -1 contains a space that can accommodate the C-6 methylol of Gal, enabling the enzyme to bypass the β-1,6-linked galactan side chains of AGPs. Furthermore, the galactan-binding domain in CBM35 has a different ligand interaction mechanism from other sugar-binding CBM35s, including those that bind galactomannan. Specifically, we noted a Gly → Trp substitution, which affects pyranose stacking, and an Asp → Asn substitution in the binding pocket, which recognizes β-linked rather than α-linked Gal residues. These findings should facilitate further structural analysis of AGPs and may also be helpful in engineering designer enzymes for efficient biomass utilization., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Matsuyama et al.)

Published

2020

21. A structural and kinetic survey of GH5_4 endoglucanases reveals determinants of broad substrate specificity and opportunities for biomass hydrolysis.

Author

Glasgow EM, Kemna EI, Bingman CA, Ing N, Deng K, Bianchetti CM, Takasuka TE, Northen TR, and Fox BG

Subjects

Ascomycota enzymology, Binding Sites, Catalytic Domain, Databases, Protein, Glucans chemistry, Glucans metabolism, Hydrolysis, Kinetics, Mannans metabolism, Molecular Dynamics Simulation, Ruminococcus enzymology, Substrate Specificity, Xylans chemistry, Xylans metabolism, Biomass, Glycoside Hydrolases metabolism

Abstract

Broad-specificity glycoside hydrolases (GHs) contribute to plant biomass hydrolysis by degrading a diverse range of polysaccharides, making them useful catalysts for renewable energy and biocommodity production. Discovery of new GHs with improved kinetic parameters or more tolerant substrate-binding sites could increase the efficiency of renewable bioenergy production even further. GH5 has over 50 subfamilies exhibiting selectivities for reaction with β-(1,4)-linked oligo- and polysaccharides. Among these, subfamily 4 (GH5_4) contains numerous broad-selectivity endoglucanases that hydrolyze cellulose, xyloglucan, and mixed-linkage glucans. We previously surveyed the whole subfamily and found over 100 new broad-specificity endoglucanases, although the structural origins of broad specificity remained unclear. A mechanistic understanding of GH5_4 substrate specificity would help inform the best protein design strategies and the most appropriate industrial application of broad-specificity endoglucanases. Here we report structures of 10 new GH5_4 enzymes from cellulolytic microbes and characterize their substrate selectivity using normalized reducing sugar assays and MS. We found that GH5_4 enzymes have the highest catalytic efficiency for hydrolysis of xyloglucan, glucomannan, and soluble β-glucans, with opportunistic secondary reactions on cellulose, mannan, and xylan. The positions of key aromatic residues determine the overall reaction rate and breadth of substrate tolerance, and they contribute to differences in oligosaccharide cleavage patterns. Our new composite model identifies several critical structural features that confer broad specificity and may be readily engineered into existing industrial enzymes. We demonstrate that GH5_4 endoglucanases can have broad specificity without sacrificing high activity, making them a valuable addition to the biomass deconstruction toolset., (Copyright © 2020.)

Published

2020

22. AI26 inhibits the ADP-ribosylhydrolase ARH3 and suppresses DNA damage repair.

Author

Liu X, Xie R, Yu LL, Chen SH, Yang X, Singh AK, Li H, Wu C, and Yu X

Subjects

Cell Line, Tumor, Glycoside Hydrolases genetics, Humans, DNA Damage, DNA Repair drug effects, Enzyme Inhibitors pharmacology, Glycoside Hydrolases antagonists & inhibitors, Glycoside Hydrolases metabolism

Abstract

The ADP-ribosylhydrolase ARH3 plays a key role in DNA damage repair, digesting poly(ADP-ribose) and removing ADP-ribose from serine residues of the substrates. Specific inhibitors that selectively target ARH3 would be a useful tool to examine DNA damage repair, as well as a possible strategy for tumor suppression. However, efforts to date have not identified any suitable compounds. Here, we used in silico and biochemistry screening to search for ARH3 inhibitors. We discovered a small molecule compound named ARH3 inhibitor 26 (AI26) as, to our knowledge, the first ARH3 inhibitor. AI26 binds to the catalytic pocket of ARH3 and inhibits the enzymatic activity of ARH3 with an estimated IC 50 of ∼2.41 μm in vitro Moreover, hydrolysis of DNA damage-induced ADP-ribosylation was clearly inhibited when cells were pretreated with AI26, leading to defects in DNA damage repair. In addition, tumor cells with DNA damage repair defects were hypersensitive to AI26 treatment, as well as combinations of AI26 and other DNA-damaging agents such as camptothecin and doxorubicin. Collectively, these results reveal not only a chemical probe to study ARH3-mediated DNA damage repair but also a chemotherapeutic strategy for tumor suppression., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Liu et al.)

Published

2020

23. Golgi-localized exo-β1,3-galactosidases involved in cell expansion and root growth in Arabidopsis .

Author

Nibbering P, Petersen BL, Motawia MS, Jørgensen B, Ulvskov P, and Niittylä T

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Galactosyltransferases genetics, Glycoside Hydrolases genetics, Mucoproteins genetics, Plant Proteins genetics, Plant Proteins metabolism, Plant Roots genetics, Arabidopsis growth & development, Arabidopsis Proteins metabolism, Galactosyltransferases metabolism, Glycoside Hydrolases metabolism, Mucoproteins metabolism, Plant Roots growth & development

Abstract

Plant arabinogalactan proteins (AGPs) are a diverse group of cell surface- and wall-associated glycoproteins. Functionally important AGP glycans are synthesized in the Golgi apparatus, but the relationships among their glycosylation levels, processing, and functionalities are poorly understood. Here, we report the identification and functional characterization of two Golgi-localized exo-β-1,3-galactosidases from the glycosyl hydrolase 43 (GH43) family in Arabidopsis thaliana GH43 loss-of-function mutants exhibited root cell expansion defects in sugar-containing growth media. This root phenotype was associated with an increase in the extent of AGP cell wall association, as demonstrated by Yariv phenylglycoside dye quantification and comprehensive microarray polymer profiling of sequentially extracted cell walls. Characterization of recombinant GH43 variants revealed that the exo-β-1,3-galactosidase activity of GH43 enzymes is hindered by β-1,6 branches on β-1,3-galactans. In line with this steric hindrance, the recombinant GH43 variants did not release galactose from cell wall-extracted glycoproteins or AGP-rich gum arabic. These results indicate that the lack of exo-β-1,3-galactosidase activity alters cell wall extensibility in roots, a phenotype that could be explained by the involvement of galactosidases in AGP glycan biosynthesis., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Nibbering et al.)

Published

2020

24. A unique combination of glycoside hydrolases in Streptococcus suis specifically and sequentially acts on host-derived αGal-epitope glycans.

Author

Chen P, Liu R, Huang M, Zhu J, Wei D, Castellino FJ, Dang G, Xie F, Li G, Cui Z, Liu S, and Zhang Y

Subjects

Animals, Bacterial Proteins genetics, Bacterial Proteins metabolism, Disaccharides chemistry, Disaccharides genetics, Disaccharides metabolism, Epitopes genetics, Epitopes metabolism, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Mice, Polysaccharides, Bacterial genetics, Polysaccharides, Bacterial metabolism, Protein Domains, Rabbits, Streptococcus suis genetics, Streptococcus suis metabolism, Swine, Bacterial Proteins chemistry, Epitopes chemistry, Glycoside Hydrolases chemistry, Polysaccharides, Bacterial chemistry, Streptococcus suis chemistry

Abstract

Infections by many bacterial pathogens rely on their ability to degrade host glycans by producing glycoside hydrolases (GHs). Here, we discovered a conserved multifunctional GH, SsGalNagA, containing a unique combination of two family 32 carbohydrate-binding modules (CBM), a GH16 domain and a GH20 domain, in the zoonotic pathogen Streptococcus suis 05ZYH33. Enzymatic assays revealed that the SsCBM-GH16 domain displays endo -(β1,4)-galactosidase activity specifically toward the host-derived αGal epitope Gal(α1,3)Gal(β1,4)Glc(NAc)-R, whereas the SsGH20 domain has a wide spectrum of exo -β- N -acetylhexosaminidase activities, including exo -(β1,3)- N -acetylglucosaminidase activity, and employs this activity to act in tandem with SsCBM-GH16 on the αGal-epitope glycan. Further, we found that the CBM32 domain adjacent to the SsGH16 domain is indispensable for SsGH16 catalytic activity. Surface plasmon resonance experiments uncovered that both CBM32 domains specifically bind to αGal-epitope glycan, and together they had a K D of 3.5 mm toward a pentasaccharide αGal-epitope glycan. Cell-binding and αGal epitope removal assays revealed that SsGalNagA efficiently binds to both swine erythrocytes and tracheal epithelial cells and removes the αGal epitope from these cells, suggesting that SsGalNagA functions in nutrient acquisition or alters host signaling in S. suis Both binding and removal activities were blocked by an αGal-epitope glycan. SsGalNagA is the first enzyme reported to sequentially act on a glycan containing the αGal epitope. These findings shed detailed light on the evolution of GHs and an important host-pathogen interaction., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Chen et al.)

Published

2020

25. A trimodular bacterial enzyme combining hydrolytic activity with oxidative glycosidic bond cleavage efficiently degrades chitin.

Author

Mekasha S, Tuveng TR, Askarian F, Choudhary S, Schmidt-Dannert C, Niebisch A, Modregger J, Vaaje-Kolstad G, and Eijsink VGH

Subjects

Actinobacteria metabolism, Bacterial Proteins metabolism, Catalysis, Cellulose metabolism, Chitin metabolism, Glycoside Hydrolases metabolism, Glycosides metabolism, Hydrolysis, Mixed Function Oxygenases metabolism, Oxidation-Reduction, Oxidative Stress physiology, Polysaccharides metabolism, Substrate Specificity, Actinobacteria enzymology, Chitinases metabolism

Abstract

Findings from recent studies have indicated that enzymes containing more than one catalytic domain may be particularly powerful in the degradation of recalcitrant polysaccharides such as chitin and cellulose. Some known multicatalytic enzymes contain several glycoside hydrolase domains and one or more carbohydrate-binding modules (CBMs). Here, using bioinformatics and biochemical analyses, we identified an enzyme, Jd 1381 from the actinobacterium Jonesia denitrificans , that uniquely combines two different polysaccharide-degrading activities. We found that Jd 1381 contains an N-terminal family AA10 lytic polysaccharide monooxygenase (LPMO), a family 5 chitin-binding domain (CBM5), and a family 18 chitinase (Chi18) domain. The full-length enzyme, which seems to be the only chitinase produced by J. denitrificans , degraded both α- and β-chitin. Both the chitinase and the LPMO activities of Jd 1381 were similar to those of other individual chitinases and LPMOs, and the overall efficiency of chitin degradation by full-length Jd 1381 depended on its chitinase and LPMO activities. Of note, the chitin-degrading activity of Jd 1381 was comparable with or exceeded the activities of combinations of well-known chitinases and an LPMO from Serratia marcescens Importantly, comparison of the chitinolytic efficiency of Jd 1381 with the efficiencies of combinations of truncated variants- Jd LPMO10 and Jd CBM5-Chi18 or Jd LPMO10-CBM5 and Jd Chi18-indicated that optimal Jd 1381 activity requires close spatial proximity of the LPMO10 and the Chi18 domains. The demonstration of intramolecular synergy between LPMOs and hydrolytic enzymes reported here opens new avenues toward the development of efficient catalysts for biomass conversion., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Mekasha et al.)

Published

2020

26. Structure-function analysis of silkworm sucrose hydrolase uncovers the mechanism of substrate specificity in GH13 subfamily 17 exo -α-glucosidases.

Author

Miyazaki T and Park EY

Subjects

Animals, Bombyx chemistry, Bombyx metabolism, Crystallography, X-Ray, Glycoside Hydrolases chemistry, Hydrolysis, Models, Molecular, Protein Conformation, Substrate Specificity, alpha-Glucosidases chemistry, Bombyx enzymology, Glycoside Hydrolases metabolism, Sucrose metabolism, alpha-Glucosidases metabolism

Abstract

The domestic silkworm Bombyx mori expresses two sucrose-hydrolyzing enzymes, BmSUH and BmSUC1, belonging to glycoside hydrolase family 13 subfamily 17 (GH13_17) and GH32, respectively. BmSUH has little activity on maltooligosaccharides, whereas other insect GH13_17 α-glucosidases are active on sucrose and maltooligosaccharides. Little is currently known about the structural mechanisms and substrate specificity of GH13_17 enzymes. In this study, we examined the crystal structures of BmSUH without ligands; in complexes with substrates, products, and inhibitors; and complexed with its covalent intermediate at 1.60-1.85 Å resolutions. These structures revealed that the conformations of amino acid residues around subsite -1 are notably different at each step of the hydrolytic reaction. Such changes have not been previously reported among GH13 enzymes, including exo - and endo -acting hydrolases, such as α-glucosidases and α-amylases. Amino acid residues at subsite +1 are not conserved in BmSUH and other GH13_17 α-glucosidases, but subsite -1 residues are absolutely conserved. Substitutions in three subsite +1 residues, Gln 191 , Tyr 251 , and Glu 440 , decreased sucrose hydrolysis and increased maltase activity of BmSUH, indicating that these residues are key for determining its substrate specificity. These results provide detailed insights into structure-function relationships in GH13 enzymes and into the molecular evolution of insect GH13_17 α-glucosidases., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Miyazaki and Park.)

Published

2020

27. Development of a novel β-1,6-glucan-specific detection system using functionally-modified recombinant endo-β-1,6-glucanase.

Author

Yamanaka D, Takatsu K, Kimura M, Swamydas M, Ohnishi H, Umeyama T, Oyama F, Lionakis MS, and Ohno N

Subjects

Animals, Candida metabolism, Enzyme Assays methods, Female, Fungal Polysaccharides metabolism, Glycoside Hydrolases genetics, Mice, Mice, Inbred C57BL, Mice, Inbred ICR, Polysaccharides metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, beta-Glucans metabolism, Biosensing Techniques methods, Fungal Polysaccharides chemistry, Glycoside Hydrolases metabolism, Polysaccharides analysis, beta-Glucans analysis

Abstract

β-1,3-d-Glucan is a ubiquitous glucose polymer produced by plants, bacteria, and most fungi. It has been used as a diagnostic tool in patients with invasive mycoses via a highly-sensitive reagent consisting of the blood coagulation system of horseshoe crab. However, no method is currently available for measuring β-1,6-glucan, another primary β-glucan structure of fungal polysaccharides. Herein, we describe the development of an economical and highly-sensitive and specific assay for β-1,6-glucan using a modified recombinant endo-β-1,6-glucanase having diminished glucan hydrolase activity. The purified β-1,6-glucanase derivative bound to the β-1,6-glucan pustulan with a K D of 16.4 nm We validated the specificity of this β-1,6-glucan probe by demonstrating its ability to detect cell wall β-1,6-glucan from both yeast and hyphal forms of the opportunistic fungal pathogen Candida albicans , without any detectable binding to glucan lacking the long β-1,6-glucan branch. We developed a sandwich ELISA-like assay with a low limit of quantification for pustulan (1.5 pg/ml), and we successfully employed this assay in the quantification of extracellular β-1,6-glucan released by >250 patient-derived strains of different Candida species (including Candida auris ) in culture supernatant in vitro We also used this assay to measure β-1,6-glucan in vivo in the serum and in several organs in a mouse model of systemic candidiasis. Our work describes a reliable method for β-1,6-glucan detection, which may prove useful for the diagnosis of invasive fungal infections., (© 2020 Yamanaka et al.)

Published

2020

28. Sulfated and sialylated N -glycans in the echinoderm Holothuria atra reflect its marine habitat and phylogeny.

Author

Vanbeselaere J, Jin C, Eckmair B, Wilson IBH, and Paschinger K

Subjects

Animals, Carbohydrate Conformation, Carbohydrate Sequence, Chromatography, High Pressure Liquid, Ecosystem, Glycoside Hydrolases metabolism, Glycosylation, Holothuria classification, Phylogeny, Polysaccharides classification, Polysaccharides metabolism, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Holothuria metabolism, Polysaccharides chemistry, Sulfates chemistry

Abstract

Among the earliest deuterostomes, the echinoderms are an evolutionary important group of ancient marine animals. Within this phylum, the holothuroids (sea cucumbers) are known to produce a wide range of glycoconjugate biopolymers with apparent benefits to health; therefore, they are of economic and culinary interest throughout the world. Other than their highly modified glycosaminoglycans ( e.g. fucosylated chondroitin sulfate and fucoidan), nothing is known about their protein-linked glycosylation. Here we used multistep N -glycan fractionation to efficiently separate anionic and neutral N -glycans before analyzing the N -glycans of the black sea cucumber ( Holothuria atra ) by MS in combination with enzymatic and chemical treatments. These analyses showed the presence of various fucosylated, phosphorylated, sialylated, and multiply sulfated moieties as modifications of oligomannosidic, hybrid, and complex-type N -glycans. The high degree of sulfation and fucosylation parallels the modifications observed previously on holothuroid glycosaminoglycans. Compatible with its phylogenetic position, H. atra not only expresses vertebrate motifs such as sulfo- and sialyl-Lewis A epitopes but displays a high degree of anionic substitution of its glycans, as observed in other marine invertebrates. Thus, as for other echinoderms, the phylum- and order-specific aspects of this species' N -glycosylation reveal both invertebrate- and vertebrate-like features., (© 2020 Vanbeselaere et al.)

Published

2020

29. Glycosylation at an evolutionary nexus: the brittle star Ophiactis savignyi expresses both vertebrate and invertebrate N -glycomic features.

Author

Eckmair B, Jin C, Karlsson NG, Abed-Navandi D, Wilson IBH, and Paschinger K

Subjects

Animals, Carbohydrate Sequence, Chromatography, High Pressure Liquid, Glycoside Hydrolases metabolism, Glycosylation, Oligosaccharides chemistry, Phylogeny, Polysaccharides classification, Polysaccharides metabolism, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Starfish classification, Glycomics methods, Polysaccharides chemistry, Starfish metabolism

Abstract

Echinoderms are among the most primitive deuterostomes and have been used as model organisms to understand chordate biology because of their close evolutionary relationship to this phylogenetic group. However, there are almost no data available regarding the N -glycomic capacity of echinoderms, which are otherwise known to produce a diverse set of species-specific glycoconjugates, including ones heavily modified by fucose, sulfate, and sialic acid residues. To increase the knowledge of diversity of carbohydrate structures within this phylum, here we conducted an in-depth analysis of N -glycans from a brittle star ( Ophiactis savignyi ) as an example member of the class Ophiuroidea. To this end, we performed a multi-step N -glycan analysis by HPLC and various exoglyosidase and chemical treatments in combination with MALDI-TOF MS and MS/MS. Using this approach, we found a wealth of hybrid and complex oligosaccharide structures reminiscent of those in higher vertebrates as well as some classical invertebrate glycan structures. 70% of these N -glycans were anionic, carrying either sialic acid, sulfate, or phosphate residues. In terms of glycophylogeny, our data position the brittle star between invertebrates and vertebrates and confirm the high diversity of N -glycosylation in lower organisms., (© 2020 Eckmair et al.)

Published

2020

30. Toward universal donor blood: Enzymatic conversion of A and B to O type.

Author

Rahfeld P and Withers SG

Subjects

Animals, Bacteria enzymology, Biocatalysis, Blood Transfusion, Hexosaminidases metabolism, Humans, Models, Molecular, alpha-Galactosidase metabolism, ABO Blood-Group System metabolism, Biotechnology methods, Blood Donors, Glycoside Hydrolases metabolism

Abstract

Transfusion of blood, or more commonly red blood cells (RBCs), is integral to health care systems worldwide but requires careful matching of blood types to avoid serious adverse consequences. Of the four main blood types, A, B, AB, and O, only O can be given to any patient. This universal donor O-type blood is crucial for emergency situations where time or resources for typing are limited, so it is often in short supply. A and B blood differ from the O type in the presence of an additional sugar antigen (GalNAc and Gal, respectively) on the core H-antigen found on O-type RBCs. Thus, conversion of A, B, and AB RBCs to O-type RBCs should be achievable by removal of that sugar with an appropriate glycosidase. The first demonstration of a B-to-O conversion by Goldstein in 1982 required massive amounts of enzyme but enabled proof-of-principle transfusions without adverse effects in humans. New α-galactosidases and α- N -acetylgalactosaminidases were identified by screening bacterial libraries in 2007, allowing improved conversion of B and the first useful conversions of A-type RBCs, although under constrained conditions. In 2019, screening of a metagenomic library derived from the feces of an AB donor enabled discovery of a significantly more efficient two-enzyme system, involving a GalNAc deacetylase and a galactosaminidase, for A conversion. This promising system works well both in standard conditions and in whole blood. We discuss remaining challenges and opportunities for the use of such enzymes in blood conversion and organ transplantation., (© 2020 Rahfeld and Withers.)

Published

2020

31. The transcription factor ACE3 controls cellulase activities and lactose metabolism via two additional regulators in the fungus Trichoderma reesei .

Author

Zhang J, Chen Y, Wu C, Liu P, Wang W, and Wei D

Subjects

Binding Sites genetics, Cellulase genetics, Fungal Proteins genetics, Gene Expression Profiling methods, Gene Expression Regulation, Fungal, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Mutation, Promoter Regions, Genetic genetics, Protein Binding, Transcription Factors genetics, Trichoderma enzymology, Trichoderma genetics, Cellulase metabolism, Fungal Proteins metabolism, Lactose metabolism, Transcription Factors metabolism, Trichoderma metabolism

Abstract

Fungi of the genus Trichoderma are a rich source of enzymes, such as cellulases and hemicellulases, that can degrade lignocellulosic biomass and are therefore of interest for biotechnological approaches seeking to optimize biofuel production. The essential transcription factor ACE3 is involved in cellulase production in Trichoderma reesei ; however, the mechanism by which ACE3 regulates cellulase activities is unknown. Here, we discovered that the nominal ace3 sequence in the T. reesei genome available through the Joint Genome Institute is erroneously annotated. Moreover, we identified the complete ace3 sequence, the ACE3 Zn(II) 2 Cys 6 domain, and the ACE3 DNA-binding sites containing a 5'-CGGAN(T/A) 3 -3' consensus. We found that in addition to its essential role in cellulase production, ace3 is required for lactose assimilation and metabolism in T. reesei Transcriptional profiling with RNA-Seq revealed that ace3 deletion down-regulates not only the bulk of the major cellulase, hemicellulase, and related transcription factor genes, but also reduces the expression of lactose metabolism-related genes. Additionally, we demonstrate that ACE3 binds the promoters of many cellulase genes, the cellulose response transporter gene crt1 , and transcription factor-encoding genes, including xyr1 We also observed that XYR1 dimerizes to facilitate cellulase production and that ACE3 interacts with XYR1. Together, these findings uncover how two essential transcriptional activators mediate cellulase gene expression in T. reesei On the basis of these observations, we propose a model of how the interactions between ACE3, Crt1, and XYR1 control cellulase expression and lactose metabolism in T. reesei ., (© 2019 Zhang et al.)

Published

2019

32. Prospecting for microbial α- N -acetylgalactosaminidases yields a new class of GH31 O -glycanase.

Author

Rahfeld P, Wardman JF, Mehr K, Huff D, Morgan-Lang C, Chen HM, Hallam SJ, and Withers SG

Subjects

Gastrointestinal Microbiome genetics, Glycoside Hydrolases chemistry, Glycoside Hydrolases isolation & purification, Glycoside Hydrolases metabolism, Glycosides metabolism, Glycosylation, Hexosaminidases metabolism, Humans, Mucins metabolism, Peptides metabolism, Polysaccharides chemistry, Proteins metabolism, Substrate Specificity, alpha-N-Acetylgalactosaminidase genetics, Glycoside Hydrolases chemical synthesis, alpha-N-Acetylgalactosaminidase metabolism

Abstract

α-Linked GalNAc (α-GalNAc) is most notably found at the nonreducing terminus of the blood type-determining A-antigen and as the initial point of attachment to the peptide backbone in mucin-type O -glycans. However, despite their ubiquity in saccharolytic microbe-rich environments such as the human gut, relatively few α- N -acetylgalactosaminidases are known. Here, to discover and characterize novel microbial enzymes that hydrolyze α-GalNAc, we screened small-insert libraries containing metagenomic DNA from the human gut microbiome. Using a simple fluorogenic glycoside substrate, we identified and characterized a glycoside hydrolase 109 (GH109) that is active on blood type A-antigen, along with a new subfamily of glycoside hydrolase 31 (GH31) that specifically cleaves the initial α-GalNAc from mucin-type O -glycans. This represents a new activity in this GH family and a potentially useful new enzyme class for analysis or modification of O -glycans on protein or cell surfaces., Competing Interests: The authors declare that they have no conflicts of interest with the contents of this article., (© 2019 Rahfeld et al.)

Published

2019

33. Ega3 from the fungal pathogen Aspergillus fumigatus is an endo-α-1,4-galactosaminidase that disrupts microbial biofilms.

Author

Bamford NC, Le Mauff F, Subramanian AS, Yip P, Millán C, Zhang Y, Zacharias C, Forman A, Nitz M, Codée JDC, Usón I, Sheppard DC, and Howell PL

Subjects

Aspergillus fumigatus genetics, Aspergillus fumigatus ultrastructure, Biofilms drug effects, Crystallography, X-Ray methods, Fungal Proteins genetics, Fungi metabolism, Glycoside Hydrolases metabolism, Hexosaminidases pharmacology, Hexosaminidases ultrastructure, Polysaccharides metabolism, Virulence, Aspergillus fumigatus metabolism, Glycoside Hydrolases genetics, Hexosaminidases metabolism

Abstract

Aspergillus fumigatus is an opportunistic fungal pathogen that causes both chronic and acute invasive infections. Galactosaminogalactan (GAG) is an integral component of the A. fumigatus biofilm matrix and a key virulence factor. GAG is a heterogeneous linear α-1,4-linked exopolysaccharide of galactose and GalNAc that is partially deacetylated after secretion. A cluster of five co-expressed genes has been linked to GAG biosynthesis and modification. One gene in this cluster, ega3, is annotated as encoding a putative α-1,4-galactosaminidase belonging to glycoside hydrolase family 114 (GH114). Herein, we show that recombinant Ega3 is an active glycoside hydrolase that disrupts GAG-dependent A. fumigatus and Pel polysaccharide-dependent Pseudomonas aeruginosa biofilms at nanomolar concentrations. Using MS and functional assays, we demonstrate that Ega3 is an endo-acting α-1,4-galactosaminidase whose activity depends on the conserved acidic residues, Asp-189 and Glu-247. X-ray crystallographic structural analysis of the apo Ega3 and an Ega3-galactosamine complex, at 1.76 and 2.09 Å resolutions, revealed a modified (β/α) 8 -fold with a deep electronegative cleft, which upon ligand binding is capped to form a tunnel. Our structural analysis coupled with in silico docking studies also uncovered the molecular determinants for galactosamine specificity and substrate binding at the -2 to +1 binding subsites. The findings in this study increase the structural and mechanistic understanding of the GH114 family, which has >600 members encoded by plant and opportunistic human pathogens, as well as in industrially used bacteria and fungi., (© 2019 Bamford et al.)

Published

2019

34. Substrate specificity, regiospecificity, and processivity in glycoside hydrolase family 74.

Author

Arnal G, Stogios PJ, Asohan J, Attia MA, Skarina T, Viborg AH, Henrissat B, Savchenko A, and Brumer H

Subjects

Bacteria enzymology, Biocatalysis, Crystallography, X-Ray, Fungi enzymology, Glycoside Hydrolases genetics, Kinetics, Models, Molecular, Protein Conformation, Stereoisomerism, Substrate Specificity, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism

Abstract

Glycoside hydrolase family 74 (GH74) is a historically important family of endo -β-glucanases. On the basis of early reports of detectable activity on cellulose and soluble cellulose derivatives, GH74 was originally considered to be a "cellulase" family, although more recent studies have generally indicated a high specificity toward the ubiquitous plant cell wall matrix glycan xyloglucan. Previous studies have indicated that GH74 xyloglucanases differ in backbone cleavage regiospecificities and can adopt three distinct hydrolytic modes of action: exo , endo -dissociative, and endo -processive. To improve functional predictions within GH74, here we coupled in-depth biochemical characterization of 17 recombinant proteins with structural biology-based investigations in the context of a comprehensive molecular phylogeny, including all previously characterized family members. Elucidation of four new GH74 tertiary structures, as well as one distantly related dual seven-bladed β-propeller protein from a marine bacterium, highlighted key structure-function relationships along protein evolutionary trajectories. We could define five phylogenetic groups, which delineated the mode of action and the regiospecificity of GH74 members. At the extremes, a major group of enzymes diverged to hydrolyze the backbone of xyloglucan nonspecifically with a dissociative mode of action and relaxed backbone regiospecificity. In contrast, a sister group of GH74 enzymes has evolved a large hydrophobic platform comprising 10 subsites, which facilitates processivity. Overall, the findings of our study refine our understanding of catalysis in GH74, providing a framework for future experimentation as well as for bioinformatics predictions of sequences emerging from (meta)genomic studies., (© 2019 Arnal et al.)

Published

2019

35. Molecular mechanism of Aspergillus fumigatus biofilm disruption by fungal and bacterial glycoside hydrolases.

Author

Le Mauff F, Bamford NC, Alnabelseya N, Zhang Y, Baker P, Robinson H, Codée JDC, Howell PL, and Sheppard DC

Subjects

Anti-Infective Agents metabolism, Aspergillus fumigatus metabolism, Biofilms growth & development, Catalytic Domain, Fungal Proteins metabolism, Fungi metabolism, Glycoside Hydrolases physiology, Hydrolysis, Polysaccharide-Lyases metabolism, Polysaccharides metabolism, Pseudomonas aeruginosa metabolism, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods, Substrate Specificity physiology, Virulence, Biofilms drug effects, Glycoside Hydrolases metabolism, Polysaccharide-Lyases ultrastructure

Abstract

During infection, the fungal pathogen Aspergillus fumigatus forms biofilms that enhance its resistance to antimicrobials and host defenses. An integral component of the biofilm matrix is galactosaminogalactan (GAG), a cationic polymer of α-1,4-linked galactose and partially deacetylated N -acetylgalactosamine (GalNAc). Recent studies have shown that recombinant hydrolase domains from Sph3, an A. fumigatus glycoside hydrolase involved in GAG synthesis, and PelA, a multifunctional protein from Pseudomonas aeruginosa involved in Pel polysaccharide biosynthesis, can degrade GAG, disrupt A. fumigatus biofilms, and attenuate fungal virulence in a mouse model of invasive aspergillosis. The molecular mechanisms by which these enzymes disrupt biofilms have not been defined. We hypothesized that the hydrolase domains of Sph3 and PelA (Sph3 h and PelA h , respectively) share structural and functional similarities given their ability to degrade GAG and disrupt A. fumigatus biofilms. MALDI-TOF enzymatic fingerprinting and NMR experiments revealed that both proteins are retaining endo-α-1,4- N- acetylgalactosaminidases with a minimal substrate size of seven residues. The crystal structure of PelA h was solved to 1.54 Å and structure alignment to Sph3 h revealed that the enzymes share similar catalytic site residues. However, differences in the substrate-binding clefts result in distinct enzyme-substrate interactions. PelA h hydrolyzed partially deacetylated substrates better than Sph3 h , a finding that agrees well with PelA h 's highly electronegative binding cleft versus the neutral surface present in Sph3 h Our insight into PelA h 's structure and function necessitate the creation of a new glycoside hydrolase family, GH166, whose structural and mechanistic features, along with those of GH135 (Sph3), are reported here.

Published

2019

36. Unraveling the subtleties of β-(1→3)-glucan phosphorylase specificity in the GH94, GH149, and GH161 glycoside hydrolase families.

Author

Kuhaudomlarp S, Pergolizzi G, Patron NJ, Henrissat B, and Field RA

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Euglena gracilis enzymology, Euglena gracilis genetics, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Ochromonas enzymology, Ochromonas genetics, Oligosaccharides chemistry, Paenibacillus polymyxa genetics, beta-Glucans chemistry, Bacterial Proteins metabolism, Glycoside Hydrolases metabolism, Oligosaccharides metabolism, Paenibacillus polymyxa enzymology, beta-Glucans metabolism

Abstract

Glycoside phosphorylases (GPs) catalyze the phosphorolysis of glycans into the corresponding sugar 1-phosphates and shortened glycan chains. Given the diversity of natural β-(1→3)-glucans and their wide range of biotechnological applications, the identification of enzymatic tools that can act on β-(1→3)-glucooligosaccharides is an attractive area of research. GP activities acting on β-(1→3)-glucooligosaccharides have been described in bacteria, the photosynthetic excavate Euglena gracilis , and the heterokont Ochromonas spp. Previously, we characterized β-(1→3)-glucan GPs from bacteria and E. gracilis , leading to their classification in glycoside hydrolase family GH149. Here, we characterized GPs from Gram-positive bacteria and heterokont algae acting on β-(1→3)-glucooligosaccharides. We identified a phosphorylase sequence from Ochromonas spp. (OcP1) together with its orthologs from other species, leading us to propose the establishment of a new GH family, designated GH161. To establish the activity of GH161 members, we recombinantly expressed a bacterial GH161 gene sequence (PapP) from the Gram-positive bacterium Paenibacillus polymyxa ATCC 842 in Escherichia coli We found that PapP acts on β-(1→3)-glucooligosaccharide acceptors with a degree of polymerization (DP) ≥ 2. This activity was distinct from that of characterized GH149 β-(1→3)-glucan phosphorylases, which operate on acceptors with DP ≥ 1. We also found that bacterial GH161 genes co-localize with genes encoding β-glucosidases and ATP-binding cassette transporters, highlighting a probable involvement of GH161 enzymes in carbohydrate degradation. Importantly, in some species, GH161 and GH94 genes were present in tandem, providing evidence that GPs from different CAZy families may work sequentially to degrade oligosaccharides., (© 2019 Kuhaudomlarp et al.)

Published

2019

37. Functional metagenomics identifies an exosialidase with an inverting catalytic mechanism that defines a new glycoside hydrolase family (GH156).

Author

Chuzel L, Ganatra MB, Rapp E, Henrissat B, and Taron CH

Subjects

Amino Acid Sequence, Bacteria classification, Bacteria genetics, Bacteria isolation & purification, Bacterial Proteins metabolism, Catalytic Domain, Enzyme Stability, Fresh Water microbiology, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Glycoside Hydrolases metabolism, Hot Temperature, Metagenomics, Molecular Sequence Data, Neuraminidase metabolism, Open Reading Frames, Phylogeny, Substrate Specificity, Bacteria enzymology, Bacterial Proteins chemistry, Bacterial Proteins genetics, Multigene Family, Neuraminidase chemistry, Neuraminidase genetics

Abstract

Exosialidases are glycoside hydrolases that remove a single terminal sialic acid residue from oligosaccharides. They are widely distributed in biology, having been found in prokaryotes, eukaryotes, and certain viruses. Most characterized prokaryotic sialidases are from organisms that are pathogenic or commensal with mammals. However, in this study, we used functional metagenomic screening to seek microbial sialidases encoded by environmental DNA isolated from an extreme ecological niche, a thermal spring. Using recombinant expression of potential exosialidase candidates and a fluorogenic sialidase substrate, we discovered an exosialidase having no homology to known sialidases. Phylogenetic analysis indicated that this protein is a member of a small family of bacterial proteins of previously unknown function. Proton NMR revealed that this enzyme functions via an inverting catalytic mechanism, a biochemical property that is distinct from those of known exosialidases. This unique inverting exosialidase defines a new CAZy glycoside hydrolase family we have designated GH156., Competing Interests: The authors declare that they have no conflicts of interest with the contents of this article., (© 2018 Chuzel et al.)

Published

2018

38. Endo-fucoidan hydrolases from glycoside hydrolase family 107 (GH107) display structural and mechanistic similarities to α-l-fucosidases from GH29.

Author

Vickers C, Liu F, Abe K, Salama-Alber O, Jenkins M, Springate CMK, Burke JE, Withers SG, and Boraston AB

Subjects

Bacterial Proteins genetics, Catalysis, Catalytic Domain, Crystallography, X-Ray, Gammaproteobacteria chemistry, Gammaproteobacteria genetics, Glycoside Hydrolases genetics, Models, Molecular, Multigene Family, Polysaccharides metabolism, Substrate Specificity, alpha-L-Fucosidase genetics, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Gammaproteobacteria enzymology, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, alpha-L-Fucosidase chemistry, alpha-L-Fucosidase metabolism

Abstract

Fucoidans are chemically complex and highly heterogeneous sulfated marine fucans from brown macro algae. Possessing a variety of physicochemical and biological activities, fucoidans are used as gelling and thickening agents in the food industry and have anticoagulant, antiviral, antitumor, antibacterial, and immune activities. Although fucoidan-depolymerizing enzymes have been identified, the molecular basis of their activity on these chemically complex polysaccharides remains largely uninvestigated. In this study, we focused on three glycoside hydrolase family 107 (GH107) enzymes: MfFcnA and two newly identified members, P5AFcnA and P19DFcnA, from a bacterial species of the genus Psychromonas Using carbohydrate-PAGE, we show that P5AFcnA and P19DFcnA are active on fucoidans that differ from those depolymerized by MfFcnA, revealing differential substrate specificity within the GH107 family. Using a combination of X-ray crystallography and NMR analyses, we further show that GH107 family enzymes share features of their structures and catalytic mechanisms with GH29 α-l-fucosidases. However, we found that GH107 enzymes have the distinction of utilizing a histidine side chain as the proposed acid/base catalyst in its retaining mechanism. Further interpretation of the structural data indicated that the active-site architectures within this family are highly variable, likely reflecting the specificity of GH107 enzymes for different fucoidan substructures. Together, these findings begin to illuminate the molecular details underpinning the biological processing of fucoidans., (© 2018 Vickers et al.)

Published

2018

39. Structural features of a bacterial cyclic α-maltosyl-(1→6)-maltose (CMM) hydrolase critical for CMM recognition and hydrolysis.

Author

Kohno M, Arakawa T, Ota H, Mori T, Nishimoto T, and Fushinobu S

Subjects

Amino Acid Sequence, Catalytic Domain, Crystallography, X-Ray, Hydrolysis, Macrocyclic Compounds chemistry, Models, Molecular, Oligosaccharides chemistry, Protein Conformation, Sequence Homology, Arthrobacter enzymology, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Macrocyclic Compounds metabolism, Oligosaccharides metabolism

Abstract

Cyclic α-maltosyl-(1→6)-maltose (CMM, cyclo -{→6)-α-d-Glc p -(1→4)-α-d-Glc p -(1→6)-α-d-Glc p -(1→4)-α-d-Glc p -(1→})is a cyclic glucotetrasaccharide with alternating α-1,4 and α-1,6 linkages. CMM is composed of two maltose units and is one of the smallest cyclic glucooligosaccharides. Although CMM is resistant to usual amylases, it is efficiently hydrolyzed by CMM hydrolase (CMMase), belonging to subfamily 20 of glycoside hydrolase family 13 (GH13_20). Here, we determined the ligand-free crystal structure of CMMase from the soil-associated bacterium Arthrobacter globiformis and its structures in complex with maltose, panose, and CMM to elucidate the structural basis of substrate recognition by CMMase. The structures disclosed that although the monomer structure consists of three domains commonly adopted by GH13 and other α-amylase-related enzymes, CMMase forms a unique wing-like dimer structure. The complex structure with CMM revealed four specific subsites, namely -3', -2, -1, and +1'. We also observed that the bound CMM molecule adopts a low-energy conformer compared with the X-ray structure of a single CMM crystal, also determined here. Comparison of the CMMase active site with those in other enzymes of the GH13_20 family revealed that three regions forming the wall of the cleft, denoted PYF (Pro-203/Tyr-204/Phe-205), CS (Cys-163/Ser-164), and Y (Tyr-168), are present only in CMMase and are involved in CMM recognition. Combinations of multiple substitutions in these regions markedly decreased the activity toward CMM, indicating that the specificity for this cyclic tetrasaccharide is supported by the entire shape of the pocket. In summary, our work uncovers the mechanistic basis for the highly specific interactions of CMMase with its substrate CMM., (© 2018 Kohno et al.)

Published

2018

40. Structure-function analyses reveal the mechanism of the ARH3-dependent hydrolysis of ADP-ribosylation.

Author

Wang M, Yuan Z, Xie R, Ma Y, Liu X, and Yu X

Subjects

Adenosine Diphosphate Ribose metabolism, Amino Acid Sequence, Catalytic Domain, Crystallography, X-Ray, DNA Damage, DNA Repair, Glutamic Acid metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, HEK293 Cells, Humans, Hydrogen Bonding, Hydrolysis, Magnesium metabolism, Mutagenesis, Site-Directed, Protein Conformation, Sequence Homology, Amino Acid, Serine metabolism, Structure-Activity Relationship, ADP-Ribosylation, Glycoside Hydrolases metabolism

Abstract

ADP-ribosylation of proteins plays key roles in multiple biological processes, including DNA damage repair. Recent evidence suggests that serine is an important acceptor for ADP-ribosylation, and that serine ADP-ribosylation is hydrolyzed by ADP-ribosylhydrolase 3 (ARH3 or ADPRHL2). However, the structural details in ARH3-mediated hydrolysis remain elusive. Here, we determined the structure of ARH3 in a complex with ADP-ribose (ADPR). Our analyses revealed a group of acidic residues in ARH3 that keep two Mg 2+ ions at the catalytic center for hydrolysis of Ser-linked ADP-ribosyl group. In particular, dynamic conformational changes involving Glu 41 were observed in the catalytic center. Our observations suggest that Mg 2+ ions together with Glu 41 and water351 are likely to mediate the cleavage of the glycosidic bond in the serine-ADPR substrate. Moreover, we found that ADPR is buried in a groove and forms multiple hydrogen bonds with the main chain and side chains of ARH3 residues. On the basis of these structural findings, we used site-directed mutagenesis to examine the functional roles of key residues in the catalytic pocket of ARH3 in mediating the hydrolysis of ADP-ribosyl from serine and DNA damage repair. Moreover, we noted that ADPR recognition is essential for the recruitment of ARH3 to DNA lesions. Taken together, our study provides structural and functional insights into the molecular mechanism by which ARH3 hydrolyzes the ADP-ribosyl group from serine and contributes to DNA damage repair., (© 2018 Wang et al.)

Published

2018

41. Structure of human ADP-ribosyl-acceptor hydrolase 3 bound to ADP-ribose reveals a conformational switch that enables specific substrate recognition.

Author

Pourfarjam Y, Ventura J, Kurinov I, Cho A, Moss J, and Kim IK

Subjects

Adenosine Diphosphate Ribose chemistry, Amino Acid Sequence, Catalysis, Catalytic Domain, Crystallography, X-Ray, Humans, Hydrolysis, Models, Molecular, Sequence Homology, Substrate Specificity, Adenosine Diphosphate Ribose metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases metabolism, Protein Conformation

Abstract

ADP-ribosyl-acceptor hydrolase 3 (ARH3) plays important roles in regulation of poly(ADP-ribosyl)ation, a reversible post-translational modification, and in maintenance of genomic integrity. ARH3 degrades poly(ADP-ribose) to protect cells from poly(ADP-ribose)-dependent cell death, reverses serine mono(ADP-ribosyl)ation, and hydrolyzes O -acetyl-ADP-ribose, a product of Sirtuin-catalyzed histone deacetylation. ARH3 preferentially hydrolyzes O -linkages attached to the anomeric C1″ of ADP-ribose; however, how ARH3 specifically recognizes and cleaves structurally diverse substrates remains unknown. Here, structures of full-length human ARH3 bound to ADP-ribose and Mg 2+ , coupled with computational modeling, reveal a dramatic conformational switch from closed to open states that enables specific substrate recognition. The glutamate flap, which blocks substrate entrance to Mg 2+ in the unliganded closed state, is ejected from the active site when substrate is bound. This closed-to-open transition significantly widens the substrate-binding channel and precisely positions the scissile 1″- O -linkage for cleavage while securing tightly 2″- and 3″-hydroxyls of ADP-ribose. Our collective data uncover an unprecedented structural plasticity of ARH3 that supports its specificity for the 1″- O -linkage in substrates and Mg 2+ -dependent catalysis., Competing Interests: The authors declare that they have no conflicts of interest with the contents of this article. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

Published

2018

42. Systems analysis of the glycoside hydrolase family 18 enzymes from Cellvibrio japonicus characterizes essential chitin degradation functions.

Author

Monge EC, Tuveng TR, Vaaje-Kolstad G, Eijsink VGH, and Gardner JG

Subjects

Acetylglucosamine analogs & derivatives, Acetylglucosamine metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Catalytic Domain, Cellvibrio growth & development, Cellvibrio metabolism, Chitinases chemistry, Chitinases genetics, Computational Biology, Gene Deletion, Glucans metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Hydrolysis, Isoenzymes chemistry, Isoenzymes genetics, Isoenzymes metabolism, Kinetics, Multigene Family, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Substrate Specificity, Systems Analysis, Bacterial Proteins metabolism, Cellvibrio enzymology, Chitin metabolism, Chitinases metabolism, Gene Expression Regulation, Bacterial, Glycoside Hydrolases metabolism, Models, Biological

Abstract

Understanding the strategies used by bacteria to degrade polysaccharides constitutes an invaluable tool for biotechnological applications. Bacteria are major mediators of polysaccharide degradation in nature; however, the complex mechanisms used to detect, degrade, and consume these substrates are not well-understood, especially for recalcitrant polysaccharides such as chitin. It has been previously shown that the model bacterial saprophyte Cellvibrio japonicus is able to catabolize chitin, but little is known about the enzymatic machinery underlying this capability. Previous analyses of the C. japonicus genome and proteome indicated the presence of four glycoside hydrolase family 18 (GH18) enzymes, and studies of the proteome indicated that all are involved in chitin utilization. Using a combination of in vitro and in vivo approaches, we have studied the roles of these four chitinases in chitin bioconversion. Genetic analyses showed that only the chi18D gene product is essential for the degradation of chitin substrates. Biochemical characterization of the four enzymes showed functional differences and synergistic effects during chitin degradation, indicating non-redundant roles in the cell. Transcriptomic studies revealed complex regulation of the chitin degradation machinery of C. japonicus and confirmed the importance of Cj Chi18D and Cj LPMO10A, a previously characterized chitin-active enzyme. With this systems biology approach, we deciphered the physiological relevance of the glycoside hydrolase family 18 enzymes for chitin degradation in C. japonicus , and the combination of in vitro and in vivo approaches provided a comprehensive understanding of the initial stages of chitin degradation by this bacterium., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

43. Identification of Euglena gracilis β-1,3-glucan phosphorylase and establishment of a new glycoside hydrolase (GH) family GH149.

Author

Kuhaudomlarp S, Patron NJ, Henrissat B, Rejzek M, Saalbach G, and Field RA

Subjects

Amino Acid Sequence, Computational Biology, Conserved Sequence, Euglena gracilis genetics, Genes, Protozoan, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Hydrolysis, Kinetics, Molecular Weight, Multigene Family, Phosphorylases chemistry, Phosphorylases genetics, Phosphorylation, Phylogeny, Proteoglycans, Proteomics methods, Protozoan Proteins chemistry, Protozoan Proteins genetics, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Sequence Alignment, Substrate Specificity, Terminology as Topic, Euglena gracilis enzymology, Glycoside Hydrolases metabolism, Glycosides metabolism, Phosphorylases metabolism, Protozoan Proteins metabolism, beta-Glucans metabolism

Abstract

Glycoside phosphorylases (EC 2.4.x.x) carry out the reversible phosphorolysis of glucan polymers, producing the corresponding sugar 1-phosphate and a shortened glycan chain. β-1,3-Glucan phosphorylase activities have been reported in the photosynthetic euglenozoan Euglena gracilis , but the cognate protein sequences have not been identified to date. Continuing our efforts to understand the glycobiology of E. gracilis , we identified a candidate phosphorylase sequence, designated EgP1, by proteomic analysis of an enriched cellular protein lysate. We expressed recombinant EgP1 in Escherichia coli and characterized it in vitro as a β-1,3-glucan phosphorylase. BLASTP identified several hundred EgP1 orthologs, most of which were from Gram-negative bacteria and had 37-91% sequence identity to EgP1. We heterologously expressed a bacterial metagenomic sequence, Pro_7066 in E. coli and confirmed it as a β-1,3-glucan phosphorylase, albeit with kinetics parameters distinct from those of EgP1. EgP1, Pro_7066, and their orthologs are classified as a new glycoside hydrolase (GH) family, designated GH149. Comparisons between GH94, EgP1, and Pro_7066 sequences revealed conservation of key amino acids required for the phosphorylase activity, suggesting a phosphorylase mechanism that is conserved between GH94 and GH149. We found bacterial GH149 genes in gene clusters containing sugar transporter and several other GH family genes, suggesting that bacterial GH149 proteins have roles in the degradation of complex carbohydrates. The Bacteroidetes GH149 genes located to previously identified polysaccharide utilization loci, implicated in the degradation of complex carbohydrates. In summary, we have identified a eukaryotic and a bacterial β-1,3-glucan phosphorylase and uncovered a new family of phosphorylases that we name GH149., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

44. Structure-guided engineering of the substrate specificity of a fungal β-glucuronidase toward triterpenoid saponins.

Author

Lv B, Sun H, Huang S, Feng X, Jiang T, and Li C

Subjects

Glucuronidase genetics, Glycoside Hydrolases genetics, Glycyrrhetinic Acid analogs & derivatives, Glycyrrhetinic Acid metabolism, Protein Engineering, Substrate Specificity, Glucuronidase metabolism, Glycoside Hydrolases metabolism, Saponins metabolism, Triterpenes metabolism

Abstract

Glycoside hydrolases (GHs) have attracted special attention in research aimed at modifying natural products by partial removal of sugar moieties to manipulate their solubility and efficacy. However, these modifications are challenging to control because the low substrate specificity of most GHs often generates undesired by-products. We previously identified a GH2-type fungal β-glucuronidase from Aspergillus oryzae ( P GUS) exhibiting promiscuous substrate specificity in hydrolysis of triterpenoid saponins. Here, we present the P GUS structure, representing the first structure of a fungal β-glucuronidase, and that of an inactive P GUS mutant in complex with the native substrate glycyrrhetic acid 3- O -mono-β-glucuronide (GAMG). P GUS displayed a homotetramer structure with each monomer comprising three distinct domains: a sugar-binding, an immunoglobulin-like β-sandwich, and a TIM barrel domain. Two catalytic residues, Glu 414 and Glu 505 , acted as acid/base and nucleophile, respectively. Structural and mutational analyses indicated that the GAMG glycan moiety is recognized by polar interactions with nine residues (Asp 162 , His 332 , Asp 414 , Tyr 469 , Tyr 473 , Asp 505 , Arg 563 , Asn 567 , and Lys 569 ) and that the aglycone moiety is recognized by aromatic stacking and by a π interaction with the four aromatic residues Tyr 469 , Phe 470 , Trp 472 , and Tyr 473 Finally, structure-guided mutagenesis to precisely manipulate P GUS substrate specificity in the biotransformation of glycyrrhizin into GAMG revealed that two amino acids, Ala 365 and Arg 563 , are critical for substrate specificity. Moreover, we obtained several mutants with dramatically improved GAMG yield (>95%). Structural analysis suggested that modulating the interaction of β-glucuronidase simultaneously toward glycan and aglycone moieties is critical for tuning its substrate specificity toward triterpenoid saponins., (© 2018 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2018

45. Discovery of α-l-arabinopyranosidases from human gut microbiome expands the diversity within glycoside hydrolase family 42.

Author

Viborg AH, Katayama T, Arakawa T, Abou Hachem M, Lo Leggio L, Kitaoka M, Svensson B, and Fushinobu S

Subjects

Amino Acid Substitution, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bifidobacterium animalis isolation & purification, Carbohydrate Conformation, Catalytic Domain, Computational Biology, Crystallography, X-Ray, Disaccharides chemistry, Ginsenosides chemistry, Ginsenosides metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Glycosides chemistry, Humans, Ligands, Models, Molecular, Molecular Docking Simulation, Mutation, Phylogeny, Protein Conformation, Protein Multimerization, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Stereoisomerism, Substrate Specificity, Bacterial Proteins metabolism, Bifidobacterium animalis enzymology, Disaccharides metabolism, Gastrointestinal Microbiome, Glycoside Hydrolases metabolism, Glycosides metabolism

Abstract

Enzymes of the glycoside hydrolase family 42 (GH42) are widespread in bacteria of the human gut microbiome and play fundamental roles in the decomposition of both milk and plant oligosaccharides. All GH42 enzymes characterized so far have β-galactosidase activity. Here, we report the existence of a GH42 subfamily that is exclusively specific for α-l-arabinopyranoside and describe the first representative of this subfamily. We found that this enzyme ( Bl Arap42B) from a probiotic Bifidobacterium species cannot hydrolyze β-galactosides. However, Bl Arap42B effectively hydrolyzed paeonolide and ginsenoside Rb2, plant glycosides containing an aromatic aglycone conjugated to α-l-arabinopyranosyl-(1,6)-β-d-glucopyranoside. Paeonolide, a natural glycoside from the roots of the plant genus Paeonia, is not hydrolyzed by classical GH42 β-galactosidases. X-ray crystallography revealed a unique Trp 345 - X 12 -Trp 358 sequence motif at the Bl Arap42B active site, as compared with a Phe- X 12 -His motif in classical GH42 β-galactosidases. This analysis also indicated that the C6 position of galactose is blocked by the aromatic side chains, hence allowing accommodation only of Ara p lacking this carbon. Automated docking of paeonolide revealed that it can fit into the Bl Ara p 42B active site. The Glc p moiety of paeonolide stacks onto the aromatic ring of the Trp 252 at subsite +1 and C4-OH is hydrogen bonded with Asp 249 Moreover, the aglycone stacks against Phe 421 from the neighboring monomer in the Bl Ara p 42B trimer, forming a proposed subsite +2. These results further support the notion that evolution of metabolic specialization can be tracked at the structural level in key enzymes facilitating degradation of specific glycans in an ecological niche., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

46. Structural insights into marine carbohydrate degradation by family GH16 κ-carrageenases.

Author

Matard-Mann M, Bernard T, Leroux C, Barbeyron T, Larocque R, Préchoux A, Jeudy A, Jam M, Nyvall Collén P, Michel G, and Czjzek M

Subjects

Catalysis, Crystallography, X-Ray, Glycoside Hydrolases chemistry, Glycoside Hydrolases classification, Kinetics, Phylogeny, Protein Conformation, Substrate Specificity, Carbohydrate Metabolism, Flavobacteriaceae enzymology, Glycoside Hydrolases metabolism, Marine Biology, Pseudoalteromonas enzymology

Abstract

Carrageenans are sulfated α-1,3-β-1,4-galactans found in the cell wall of some red algae that are practically valuable for their gelation and biomimetic properties but also serve as a potential carbon source for marine bacteria. Carbohydrate degradation has been studied extensively for terrestrial plant/bacterial systems, but sulfation is not present in these cases, meaning the marine enzymes used to degrade carrageenans must possess unique features to recognize these modifications. To gain insights into these features, we have focused on κ-carrageenases from two distant bacterial phyla, which belong to glycoside hydrolase family 16 and cleave the β-1,4 linkage of κ-carrageenan. We have solved the crystal structure of the catalytic module of Zg CgkA from Zobellia galactanivorans at 1.66 Å resolution and compared it with the only other structure available, that of Pc CgkA from Pseudoalteromonas carrageenovora 9 T (ATCC 43555 T ). We also describe the first substrate complex in the inactivated mutant form of Pc CgkA at 1.7 Å resolution. The structural and biochemical comparison of these enzymes suggests key determinants that underlie the functional properties of this subfamily. In particular, we identified several arginine residues that interact with the polyanionic substrate, and confirmed the functional relevance of these amino acids using a targeted mutagenesis strategy. These results give new insight into the diversity of the κ-carrageenase subfamily. The phylogenetic analyses show the presence of several distinct clades of enzymes that relate to differences in modes of action or subtle differences within the same substrate specificity, matching the hybrid character of the κ-carrageenan polymer., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

47. Discovery and characterization of family 39 glycoside hydrolases from rumen anaerobic fungi with polyspecific activity on rare arabinosyl substrates.

Author

Jones DR, Uddin MS, Gruninger RJ, Pham TTM, Thomas D, Boraston AB, Briggs J, Pluvinage B, McAllister TA, Forster RJ, Tsang A, Selinger LB, and Abbott DW

Subjects

Animals, Glycoside Hydrolases chemistry, Substrate Specificity, Fungi enzymology, Glycoside Hydrolases metabolism, Rumen microbiology

Abstract

Enzyme activities that improve digestion of recalcitrant plant cell wall polysaccharides may offer solutions for sustainable industries. To this end, anaerobic fungi in the rumen have been identified as a promising source of novel carbohydrate active enzymes (CAZymes) that modify plant cell wall polysaccharides and other complex glycans. Many CAZymes share insufficient sequence identity to characterized proteins from other microbial ecosystems to infer their function; thus presenting challenges to their identification. In this study, four rumen fungal genes ( nf2152 , nf2215 , nf2523 , and pr2455 ) were identified that encode family 39 glycoside hydrolases (GH39s), and have conserved structural features with GH51s. Two recombinant proteins, NF2152 and NF2523, were characterized using a variety of biochemical and structural techniques, and were determined to have distinct catalytic activities. NF2152 releases a single product, β1,2-arabinobiose (Ara 2 ) from sugar beet arabinan (SBA), and β1,2-Ara 2 and α-1,2-galactoarabinose (Gal-Ara) from rye arabinoxylan (RAX). NF2523 exclusively releases α-1,2-Gal-Ara from RAX, which represents the first description of a galacto-(α-1,2)-arabinosidase. Both β-1,2-Ara 2 and α-1,2-Gal-Ara are disaccharides not previously described within SBA and RAX. In this regard, the enzymes studied here may represent valuable new biocatalytic tools for investigating the structures of rare arabinosyl-containing glycans, and potentially for facilitating their modification in industrial applications., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

48. The first crystal structure of a family 129 glycoside hydrolase from a probiotic bacterium reveals critical residues and metal cofactors.

Author

Sato M, Liebschner D, Yamada Y, Matsugaki N, Arakawa T, Wills SS, Hattie M, Stubbs KA, Ito T, Senda T, Ashida H, and Fushinobu S

Subjects

Acetylgalactosamine chemistry, Amino Acid Sequence, Amino Acid Substitution, Bacterial Proteins antagonists & inhibitors, Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Catalytic Domain, Coenzymes chemistry, Conserved Sequence, Crystallography, X-Ray, Enzyme Inhibitors chemistry, Enzyme Inhibitors metabolism, Enzyme Inhibitors pharmacology, Glycoside Hydrolases antagonists & inhibitors, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Ligands, Metals chemistry, Models, Molecular, Mutagenesis, Site-Directed, Mutation, Probiotics, Protein Conformation, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins metabolism, Sequence Alignment, Structural Homology, Protein, alpha-N-Acetylgalactosaminidase antagonists & inhibitors, alpha-N-Acetylgalactosaminidase chemistry, alpha-N-Acetylgalactosaminidase genetics, Acetylgalactosamine metabolism, Bacterial Proteins metabolism, Bifidobacterium bifidum enzymology, Coenzymes metabolism, Glycoside Hydrolases metabolism, Metals metabolism, alpha-N-Acetylgalactosaminidase metabolism

Abstract

The α- N -acetylgalactosaminidase from the probiotic bacterium Bifidobacterium bifidum (NagBb) belongs to the glycoside hydrolase family 129 and hydrolyzes the glycosidic bond of Tn-antigen (GalNAcα1-Ser/Thr). NagBb is involved in assimilation of O -glycans on mucin glycoproteins by B. bifidum in the human gastrointestinal tract, but its catalytic mechanism has remained elusive because of a lack of sequence homology around putative catalytic residues and of other structural information. Here we report the X-ray crystal structure of NagBb, representing the first GH129 family structure, solved by the single-wavelength anomalous dispersion method based on sulfur atoms of the native protein. We determined ligand-free, GalNAc, and inhibitor complex forms of NagBb and found that Asp-435 and Glu-478 are located in the catalytic domain at appropriate positions for direct nucleophilic attack at the anomeric carbon and proton donation for the glycosidic bond oxygen, respectively. A highly conserved Asp-330 forms a hydrogen bond with the O4 hydroxyl of GalNAc in the -1 subsite, and Trp-398 provides a stacking platform for the GalNAc pyranose ring. Interestingly, a metal ion, presumably Ca 2+ , is involved in the recognition of the GalNAc N -acetyl group. Mutations at Asp-435, Glu-478, Asp-330, and Trp-398 and residues involved in metal coordination (including an all-Ala quadruple mutant) significantly reduced the activity, indicating that these residues and the metal ion play important roles in substrate recognition and catalysis. Interestingly, NagBb exhibited some structural similarities to the GH101 endo-α- N -acetylgalactosaminidases, but several critical differences in substrate recognition and reaction mechanism account for the different activities of these two enzymes., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

49. Structural Insights into the Broad Substrate Specificity of a Novel Endoglycoceramidase I Belonging to a New Subfamily of GH5 Glycosidases.

Author

Han YB, Chen LQ, Li Z, Tan YM, Feng Y, and Yang GY

Subjects

Amino Acid Sequence, Cloning, Molecular, Crystallography, X-Ray, G(M1) Ganglioside metabolism, G(M3) Ganglioside metabolism, Glycoside Hydrolases chemistry, Glycoside Hydrolases genetics, Models, Molecular, Phylogeny, Protein Conformation, Protein Engineering, Rhodococcus equi chemistry, Rhodococcus equi genetics, Rhodococcus equi metabolism, Sequence Alignment, Substrate Specificity, Glycoside Hydrolases metabolism, Rhodococcus equi enzymology

Abstract

Endoglycoceramidases (EGCases) specifically hydrolyze the glycosidic linkage between the oligosaccharide and the ceramide moieties of various glycosphingolipids, and they have received substantial attention in the emerging field of glycosphingolipidology. However, the mechanism regulating the strict substrate specificity of these GH5 glycosidases has not been identified. In this study, we report a novel EGCase I from Rhodococcus equi 103S (103S_EGCase I) with remarkably broad substrate specificity. Based on phylogenetic analyses, the enzyme may represent a new subfamily of GH5 glycosidases. The X-ray crystal structures of 103S_EGCase I alone and in complex with its substrates monosialodihexosylganglioside (GM3) and monosialotetrahexosylganglioside (GM1) enabled us to identify several structural features that may account for its broad specificity. Compared with EGCase II from Rhodococcus sp. M-777 (M777_EGCase II), which possesses strict substrate specificity, 103S_EGCase I possesses a longer α7-helix and a shorter loop 4, which forms a larger substrate-binding pocket that could accommodate more extended oligosaccharides. In addition, loop 2 and loop 8 of the enzyme adopt a more open conformation, which also enlarges the oligosaccharide-binding cavity. Based on this knowledge, a rationally designed experiment was performed to examine the substrate specificity of EGCase II. The truncation of loop 4 in M777_EGCase II increased its activity toward GM1 (163%). Remarkably, the S63G mutant of M777_EGCase II showed a broader substrate spectra and significantly increased activity toward bulky substrates (up to >1370-fold for fucosyl-GM1). Collectively, the results presented here reveal the exquisite substrate recognition mechanism of EGCases and provide an opportunity for further engineering of these enzymes., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

50. The Structure of an Archaeal β-Glucosaminidase Provides Insight into Glycoside Hydrolase Evolution.

Author

Mine S, Watanabe M, Kamachi S, Abe Y, and Ueda T

Subjects

Amino Acid Sequence, Catalytic Domain, Crystallography, X-Ray, Evolution, Molecular, Glucosamine metabolism, Glycoside Hydrolases metabolism, Hexosaminidases metabolism, Models, Molecular, Protein Conformation, Protein Multimerization, Pyrococcus horikoshii chemistry, Pyrococcus horikoshii metabolism, Substrate Specificity, Thermococcus chemistry, Thermococcus metabolism, Glycoside Hydrolases chemistry, Hexosaminidases chemistry, Pyrococcus horikoshii enzymology, Thermococcus enzymology

Abstract

The archaeal exo-β-d-glucosaminidase (GlmA) is a dimeric enzyme that hydrolyzes chitosan oligosaccharides into monomer glucosamines. GlmA is a member of the glycosidase hydrolase (GH)-A superfamily-subfamily 35 and is a novel enzyme in terms of its primary structure. Here, we present the crystal structure of GlmA in complex with glucosamine at 1.27 Å resolution. The structure reveals that a monomeric form of GlmA shares structural homology with GH42 β-galactosidases, whereas most of the spatial positions of the active site residues are identical to those of GH35 β-galactosidases. We found that upon dimerization, the active site of GlmA changes shape, enhancing its ability to hydrolyze the smaller substrate in a manner similar to that of homotrimeric GH42 β-galactosidase. However, GlmA can differentiate glucosamine from galactose based on one charged residue while using the "evolutionary heritage residue" it shares with GH35 β-galactosidase. Our study suggests that GH35 and GH42 β-galactosidases evolved by exploiting the structural features of GlmA., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017