Biotechnological potential of novel glycoside hydrolase family 70 enzymes synthesizing α-glucans from starch and sucrose

Transglucosidases belonging to the glycoside hydrolase (GH) family 70 are promising enzymatic tools for the synthesis of α-glucans with defined structures from renewable sucrose and starch substrates. Depending on the GH70 enzyme specificity, α-glucans with different structures and physicochemical properties are produced, which have found diverse (potential) commercial applications, e.g. in food, health and as biomaterials. Originally, the GH70 family was established only for glucansucrase enzymes of lactic acid bacteria that catalyze the synthesis of α-glucan polymers from sucrose. In recent years, we have identified 3 novel subfamilies of GH70 enzymes (designated GtfB, GtfC and GtfD), inactive on sucrose but converting starch/maltodextrin substrates into novel α-glucans. These novel starch-acting enzymes considerably enlarge the panel of α-glucans that can be produced. They also represent very interesting evolutionary intermediates between sucrose-acting GH70 glucansucrases and starch-acting GH13 α-amylases. Here we provide an overview of the repertoire of GH70 enzymes currently available with focus on these novel starch-acting GH70 enzymes and their biotechnological potential. Moreover, we discuss key developments in the understanding of structure-function relationships of GH70 enzymes in the light of available three-dimensional structures, and the protein engineering strategies that were recently applied to expand their natural product specificities.     

4,6-α-Glucanotransferase activity occurs more widespread in Lactobacillus strains and constitutes a separate GH70 subfamily

Family 70 glycoside hydrolase glucansucrase enzymes exclusively occur in lactic acid bacteria and synthesize a wide range of α-d-glucan (abbreviated as α-glucan) oligo- and polysaccharides. Of the 47 characterized GH70 enzymes, 46 use sucrose as glucose donor. A single GH70 enzyme was recently found to be inactive with sucrose and to utilize maltooligosaccharides [(1→4)-α-d-glucooligosaccharides] as glucose donor substrates for α-glucan synthesis, acting as a 4,6-α-glucanotransferase (4,6-αGT) enzyme. Here, we report the characterization of two further GH70 4,6-αGT enzymes, i.e., from Lactobacillus reuteri strains DSM 20016 and ML1, which use maltooligosaccharides as glucose donor. Both enzymes cleave α1→4 glycosidic linkages and add the released glucose moieties one by one to the non-reducing end of growing linear α-glucan chains via α1→6 glycosidic linkages (α1→4 to α1→6 transfer activity). In this way, they convert pure maltooligosaccharide substrates into linear α-glucan product mixtures with about 50% α1→6 glycosidic bonds (isomalto/maltooligosaccharides). These new α-glucan products may provide an exciting type of carbohydrate for the food industry. The results show that 4,6-αGTs occur more widespread in family GH70 and can be considered as a GH70 subfamily. Sequence analysis allowed identification of amino acid residues in acceptor substrate binding subsites +1 and +2, differing between GH70 GTF and 4,6-αGT enzymes.     

Biochemical and crystallographic characterization of a glucansucrase from Lactobacillus reuteri 180

Glucansucrases are large extracellular transglycosidases secreted by lactic acid bacteria. Using sucrose as a substrate they synthesize high molecular mass α-glucans or, in the presence of suitable acceptor molecules, low molecular mass oligosaccharides. Although about 60 glucansucrases have been classified in glycoside hydrolase family GH70, no three-dimensional structure has been reported for any. With the aim of solving the first structure of a GH70 glucansucrase, purification and crystallization experiments were performed with a fully active, 117 kDa N-terminally truncated fragment of glucansucrase GTF180 from Lactobacillus reuteri 180 (residues 742–1772). Crystallization experiments yielded crystals that belong to two different triclinic crystal forms (space group P1) and one orthorhombic crystal form (space group P2₁2₁2₁). Native data sets for both triclinic and the orthorhombic crystals were collected at 1.7 and 2.0 Å resolution, respectively. Enzyme activity assays, pH and temperature optima show comparable values for both the full-length and the N-terminally truncated GTF180.     

The Gram-negative bacterium Azotobacter chroococcum NCIMB 8003 employs a new glycoside hydrolase family 70 4,6-α-glucanotransferase enzyme (GtfD) to synthesize a reuteran like polymer from maltodextrins and starch

BackgroundOriginally the glycoside hydrolase (GH) family 70 only comprised glucansucrases of lactic acid bacteria which synthesize α-glucan polymers from sucrose. Recently we have identified 2 novel subfamilies of GH70 enzymes represented by the Lactobacillus reuteri 121 GtfB and the Exiguobacterium sibiricum 255-15 GtfC enzymes. Both enzymes catalyze the cleavage of (α1 → 4) linkages in maltodextrin/starch and the synthesis of consecutive (α1 → 6) linkages. Here we describe a novel GH70 enzyme from the nitrogen-fixing Gram-negative bacterium Azotobacter chroococcum, designated as GtfD.MethodsThe purified recombinant GtfD enzyme was biochemically characterized using the amylose-staining assay and its products were identified using profiling chromatographic techniques (TLC and HPAEC-PAD). Glucans produced by the GtfD enzyme were analyzed by HPSEC-MALLS-RI, methylation analysis, 1D/2D [1]H/[13]C NMR spectroscopy and enzymatic degradation studies.ResultsThe A. chroococcum GtfD is closely related to GtfC enzymes, sharing the same non-permuted domain organization also found in GH13 enzymes and displaying 4,6-α-glucanotransferase activity. However, the GtfD enzyme is unable to synthesize consecutive (α1 → 6) glucosidic bonds. Instead, it forms a high molecular mass and branched α-glucan with alternating (α1 → 4) and (α1 → 6) linkages from amylose/starch, highly similar to the reuteran polymer synthesized by the L. reuteri GtfA glucansucrase from sucrose.ConclusionsIn view of its origin and specificity, the GtfD enzyme represents a unique evolutionary intermediate between family GH13 (α-amylase) and GH70 (glucansucrase) enzymes.General significanceThis study expands the natural repertoire of starch-converting enzymes providing the first characterization of an enzyme that converts starch into a reuteran-like α-glucan polymer, regarded as a health promoting food ingredient.     

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

Abstract

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

Residue Leu940 Has a Crucial Role in the Linkage and Reaction Specificity of the Glucansucrase GTF180 of the Probiotic Bacterium Lactobacillus reuteri 180

Highly conserved glycoside hydrolase family 70 glucansucrases are able to catalyze the synthesis of α-glucans with different structure from sucrose. The structural determinants of glucansucrase specificity have remained unclear. Residue Leu⁹⁴⁰ in domain B of GTF180, the glucansucrase of the probiotic bacterium Lactobacillus reuteri 180, was shown to vary in different glucansucrases and is close to the +1 glucosyl unit in the crystal structure of GTF180-ΔN in complex with maltose. Herein, we show that mutations in Leu⁹⁴⁰ of wild-type GTF180-ΔN all caused an increased percentage of (α1→6) linkages and a decreased percentage of (α1→3) linkages in the products. α-Glucans with potential different physicochemical properties (containing 67–100% of (α1→6) linkages) were produced by GTF180 and its Leu⁹⁴⁰ mutants. Mutant L940W was unable to form (α1→3) linkages and synthesized a smaller and linear glucan polysaccharide with only (α1→6) linkages. Docking studies revealed that the introduction of the large aromatic amino acid residue tryptophan at position 940 partially blocked the binding groove, preventing the isomalto-oligosaccharide acceptor to bind in an favorable orientation for the formation of (α1→3) linkages. Our data showed that the reaction specificity of GTF180 mutant was shifted either to increased polysaccharide synthesis (L940A, L940S, L940E, and L940F) or increased oligosaccharide synthesis (L940W). The L940W mutant is capable of producing a large amount of isomalto-oligosaccharides using released glucose from sucrose as acceptors. Thus, residue Leu⁹⁴⁰ in domain B is crucial for linkage and reaction specificity of GTF180. This study provides clear and novel insights into the structure-function relationships of glucansucrase enzymes.     

Characterization of the Functional Roles of Amino Acid Residues in Acceptor-binding Subsite +1 in the Active Site of the Glucansucrase GTF180 from Lactobacillus reuteri 180

α-Glucans produced by glucansucrase enzymes hold strong potential for industrial applications. The exact determinants of the linkage specificity of glucansucrase enzymes have remained largely unknown, even with the recent elucidation of glucansucrase crystal structures. Guided by the crystal structure of glucansucrase GTF180-ΔN from Lactobacillus reuteri 180 in complex with the acceptor substrate maltose, we identified several residues (Asp-1028 and Asn-1029 from domain A, as well as Leu-938, Ala-978, and Leu-981 from domain B) near subsite +1 that may be critical for linkage specificity determination, and we investigated these by random site-directed mutagenesis. First, mutants of Ala-978 (to Leu, Pro, Phe, or Tyr) and Asp-1028 (to Tyr or Trp) with larger side chains showed reduced degrees of branching, likely due to the steric hindrance by these bulky residues. Second, Leu-938 mutants (except L938F) and Asp-1028 mutants showed altered linkage specificity, mostly with increased (α1→6) linkage synthesis. Third, mutation of Leu-981 and Asn-1029 significantly affected the transglycosylation reaction, indicating their essential roles in acceptor substrate binding. In conclusion, glucansucrase product specificity is determined by an interplay of domain A and B residues surrounding the acceptor substrate binding groove. Residues surrounding the +1 subsite thus are critical for activity and specificity of the GTF180 enzyme and play different roles in the enzyme functions. This study provides novel insights into the structure-function relationships of glucansucrase enzymes and clearly shows the potential of enzyme engineering to produce tailor-made α-glucans.     

Structure-Function Relationships of Glucansucrase and Fructansucrase Enzymes from Lactic Acid Bacteria

Lactic acid bacteria (LAB) employ sucrase-type enzymes to convert sucrose into homopolysaccharides consisting of either glucosyl units (glucans) or fructosyl units (fructans). The enzymes involved are labeled glucansucrases (GS) and fructansucrases (FS), respectively. The available molecular, biochemical, and structural information on sucrase genes and enzymes from various LAB and their fructan and α-glucan products is reviewed. The GSand FS enzymes are both glycoside hydrolase enzymes that act on the same substrate (sucrose) and catalyze (retaining) transglycosylation reactions that result in polysaccharide formation, but they possess completely different protein structures. GS enzymes (family GH70) are large multidomain proteins that occur exclusively in LAB. Their catalytic domain displays clear secondary-structure similarity with α-amylase enzymes (family GH13), with a predicted permuted (β/α)₈ barrel structure for which detailed structural and mechanistic information is available. Emphasis now is on identification of residues and regions important for GS enzyme activity and product specificity (synthesis of α-glucans differing in glycosidic linkage type, degree and type of branching, glucan molecular mass, and solubility). FS enzymes (family GH68) occur in both gram-negative and gram-positive bacteria and synthesize β-fructan polymers with either β-(2→6) (inulin) or β-(2→1) (levan) glycosidic bonds. Recently, the first high-resolution three-dimensional structures have become available for FS (levansucrase) proteins, revealing a rare five-bladed β-propeller structure with a deep, negatively charged central pocket. Although these structures have provided detailed mechanistic insights, the structural features in FS enzymes dictating the synthesis of either β-(2→6) or β-(2→1) linkages, degree and type of branching, and fructan molecular mass remain to be identified.     

Screening and Application of Microbial Esterases for the Enantioselective Synthesis of Chiral Glycerol Derivatives

Glucansucrases from family 70 of glycoside-hydrolases catalyse the synthesis of α-glucans with various types of osidic linkages from sucrose. Among these enzymes, alternansucrase (ASR) and dextransucrase E (DSR-E) catalyse the formation of unusual α-glucans. ASR catalyses the synthesis of linear glucan with α-1,3 and α-1,6 alternating linkages and DSR-E synthesizes a glucan containing α-1,6 linkages in the linear chain and α-1,2 branches. The sequence analysis of these enzymes enabled the identification of structural elements suspected to be involved in the enzyme specificities. Biochemical characterization of ASR and DSR-E variants obtained from gene truncations or site-directed mutagenesis experiments showed that the specificity of these enzymes to form different types of osidic linkage is controlled by two different approaches. For ASR, the double specificity is controlled by only one catalytic domain where important amino acids involved in the enzyme specificity have been identified. In the case of DSR-E, the double specificity is controlled by two different catalytic domains both belonging to family 70, each domain being specific of one type of linkage.     

Molecular characterization and expression analysis of the glucansucrase DSRWC from Weissella cibaria synthesizing a α(1→6) glucan

Weissella cibaria isolated from human saliva produces a soluble glucan that predominantly has α-1,6-glucosidic type linkages. Using degenerated primers that were selected based on the amino acid sequences of conserved regions from known glucansucrases, a single 2.7-kb fragment was isolated. In subsequent steps, a 4969-bp product was obtained using inverse PCR. The coding region for the glucansucrase gene ( dsrWC ) consisted of a 4419-bp ORF that encoded a 1472-amino acid protein with a calculated molecular mass of 161.998 Da. The produced DSRWC glucansucrases exhibited similarity with the enzymes of the glucosylhydrolase family 70, which includes the Lactobacillus fermentum glucansucrase. The expressed recombinant DSRWC (rDSRWC) synthesized oligosaccharides in the presence of maltose or isomaltose as an acceptor and the synthesized products included α-1,6-linked glucosyl residues in addition to the maltosyl or isomaltosyl residue. rDSRWC synthesized water-soluble polymers using sucrose as substrate. According to the ¹³C-nuclear magnetic resonance analysis, the polymer that was synthesized by rDSRWC was a linear dextran, which formed predominately α-1,6-glucosidic linkages. This is the first report on the molecular characterization of glucansucrase from a W. cibaria strain.     

Glucansucrases: mechanism of action and structure-function relationships

Glucansucrases are produced principally by Leuconostoc mesenteroides and oral Streptococcus species, but also by the lactic acid bacteria (Lactococci, Lactobacilli). They catalyse the synthesis of high molecular weight D-glucose polymers, named glucans, from sucrose. In the presence of efficient acceptors, they catalyse the synthesis of low molecular weight oligosaccharides. Glucosidic bond synthesis occurs without the mediation of nucleotide activated sugars and cofactors are not necessary. Glucansucrases have an industrial value because of the production of dextrans and oligosaccharides and a biological importance by their key role in the cariogenic process. They were identified more than 50 years ago. The first glucansucrase encoding gene was cloned more than 10 years ago. But the mechanism of their action remains incompletely understood. However, in order to synthesise oligosaccharides of biological interest or to develop vaccines against dental caries, elucidation of the factors determining the regiospecificity and the regioselectivity of glucansucrases is necessary. The cloning of glucansucrase encoding genes in addition to structure-function relationship studies have allowed the identification of important amino acid residues and have shown that glucansucrases are composed of two functional domains: a core region (ca. 1000 amino acids) involved in sucrose binding and splitting and a C-terminal domain (ca. 500 amino acids) composed of a series of tandem repeats involved in glucan binding. Enzymology studies have enabled different models for their action mechanism to be proposed. The use of secondary structure prediction has led to a clearer knowledge of structure-function relationships of glucansucrases. However, mainly due to the large size of these enzymes, data on the three-dimensional structure of glucansucrases (given by crystallography and modelling) remain necessary to clearly identify those features which determine function.     

Molecular evolution of plant β-glucan endohydrolases

The evolutionary relationships of two classes of plant β-glucan endohydrolases have been examined by comparison of their substrate specificities, their three-dimensional conformations and the structural features of their corresponding genes. These comparative studies provide compelling evidence that the (1→3)-β-glucanases and (1→3,1→4)-β-glucanases from higher plants share a common ancestry and, in all likelihood, that the (1→3,1→4)-β-glucanases diverged from the (1→3)-β-glucanases during the appearance of the graminaceous monocotyledons. The evolution of (1→3,1→4)-β-glucanases from (1→3)-β-glucanases does not appear to have invoked ‘modular’ mechanisms of change, such as those caused by exon shuffling or recombination. Instead, the shift in specificity has been acquired through a limited number of point mutations that have resulted in amino acid substitutions along the substrate-binding cleft. This is consistent with current theories that the evolution of new enzymic activity is often achieved through duplication of the gene encoding an existing enzyme which is capable of performing the required chemistry, in this case the hydrolysis of a glycosidic linkage, followed by the mutational alteration and fine-tuning of substrate specificity. The evolution of a new specificity has enabled a dramatic shift in the functional capabilities of the enzymes. (1→3)-β-Glucanases that play a major role, inter alia, in the protection of the plant against pathogenic microorganisms through their ability to hydrolyse the (1→3)-β-glucans of fungal cell walls, appear to have been recruited to generate (1→3,1→4)-β-glucanases, which quite specifically hydrolyse plant cell wall (1→3,1→4)-β-glucans in the graminaecous monocotyledons during normal wall metabolism. Thus, one class of β-glucan endohydrolase can degrade β-glucans in fungal walls, while the other hydrolyses structurally distinct β-glucans of plant cell walls. Detailed information on the three-dimensional structures of the enzymes and the identification of catalytic amino acids now present opportunities to explore the precise molecular and atomic details of substrate-binding, catalytic mechanisms and the sequence of molecular events that resulted in the evolution of the substrate specificities of the two classes of enzyme.     

Crystal structure of glucansucrase from the dental caries pathogen Streptococcus mutans

Glucansucrase (GSase) from Streptococcus mutans is an essential agent in dental caries pathogenesis. Here, we report the crystal structure of S. mutans glycosyltransferase (GTF-SI), which synthesizes soluble and insoluble glucans and is a glycoside hydrolase (GH) family 70 GSase in the free enzyme form and in complex with acarbose and maltose. Resolution of the GTF-SI structure confirmed that the domain order of GTF-SI is circularly permuted as compared to that of GH family 13 α-amylases. As a result, domains A, B and IV of GTF-SI are each composed of two separate polypeptide chains. Structural comparison of GTF-SI and amylosucrase, which is closely related to GH family 13 amylases, indicated that the two enzymes share a similar transglycosylation mechanism via a glycosyl-enzyme intermediate in subsite − 1. On the other hand, novel structural features were revealed in subsites + 1 and + 2 of GTF-SI. Trp517 provided the platform for glycosyl acceptor binding, while Tyr430, Asn481 and Ser589, which are conserved in family 70 enzymes but not in family 13 enzymes, comprised subsite + 1. Based on the structure of GTF-SI and amino acid comparison of GTF-SI, GTF-I and GTF-S, Asp593 in GTF-SI appeared to be the most critical point for acceptor sugar orientation, influencing the transglycosylation specificity of GSases, that is, whether they produced insoluble glucan with α(1-3) glycosidic linkages or soluble glucan with α(1-6) linkages. The structural information derived from the current study should be extremely useful in the design of novel inhibitors that prevent the biofilm formation by GTF-SI.     

Enzymatic synthesis of l-DOPA α-glycosides by reaction with sucrose catalyzed by four different glucansucrases from four strains of Leuconostoc mesenteroides

l-DOPA α-glycosides were synthesized by reaction of l-DOPA with sucrose, catalyzed by four different glucansucrases from Leuconostoc mesenteroides B-512FMC, B-742CB, B-1299A, and B-1355C. The glucansucrases catalyzed the transfer of d-glucose from sucrose to the phenolic hydroxyl position-3 and -4 of l-DOPA. The glycosides were fractionated and purified by Bio-Gel P-2 column chromatography, and the structures were determined by ¹H NMR spectroscopy. The major glycoside was 4-O-α-d-glucopyranosyl l-DOPA, and the minor glycoside was 3-O-α-d-glucopyranosyl l-DOPA. The two glycosides were formed by all four of the glucansucrases. The ratio of the 4-O-α-glycoside to the 3-O-α-glycoside produced by the B-512FMC dextransucrase was higher than that for the other three glucansucrases. The glycosylation of l-DOPA significantly reduced the oxidation of the phenolic hydroxyl groups, which prevents their methylation, potentially increasing the use of l-DOPA in the treatment of Parkinson’s disease. The use of one enzyme, glucansucrase, and sucrose as the d-glucosyl donor makes the synthesis considerably simpler and cheaper than the formerly published procedure using cyclomaltodextrin and cyclomaltodextrin glucanyltransferase, followed by glucoamylase, and β-amylase hydrolysis.     

Characterization of substrate and product specificity of the purified recombinant glycogen branching enzyme of Rhodothermus obamensis

Background

Glycogen and starch branching enzymes catalyze the formation of α(1 → 6) linkages in storage polysaccharides by rearrangement of preexisting α-glucans. This reaction occurs through the cleavage of α(1 → 4) linkage and transfer in α(1 → 6) of the fragment in non-reducing position. These enzymes define major elements that control the structure of both glycogen and starch.

Methods

The kinetic parameters of the branching enzyme of Rhodothermus obamensis (RoBE) were established after in vitro incubation with different branched or unbranched α-glucans of controlled structure.

Results

A minimal chain length of ten glucosyl units was required for the donor substrate to be recognized by RoBE that essentially produces branches of DP 3–8. We show that RoBE preferentially creates new branches by intermolecular mechanism. Branched glucans define better substrates for the enzyme leading to the formation of hyper-branched particles of 30–70 nm in diameter (dextrins). Interestingly, RoBE catalyzes an additional α-4-glucanotransferase activity not described so far for a member of the GH13 family.

Conclusions

RoBE is able to transfer α(1 → 4)-linked-glucan in C4 position (instead of C6 position for the branching activity) of a glucan to create new α(1 → 4) linkages yielding to the elongation of linear chains subsequently used for further branching. This result is a novel case for the thin border that exists between enzymes of the GH13 family.

General significance

This work reveals the original catalytic properties of the thermostable branching enzyme of R. obamensis. It defines new approach to produce highly branched α-glucan particles in vitro.     

Crystal structure and substrate recognition mechanism of Aspergillus oryzae isoprimeverose-producing enzyme

Isoprimeverose-producing enzymes (IPases) release isoprimeverose (α-d-xylopyranosyl-(1?→?6)-d-glucopyranose) from the non-reducing end of xyloglucan oligosaccharides. Aspergillus oryzae IPase (IpeA) is classified as a member of the glycoside hydrolase family 3 (GH3); however, it has unusual substrate specificity compared with other GH3 enzymes. Xylopyranosyl branching at the non-reducing ends of xyloglucan oligosaccharides is vital for IpeA activity. We solved the crystal structure of IpeA with isoprimeverose at 2.4?Å resolution, showing that the structure of IpeA formed a dimer and was composed of three domains: an N-terminal (β/α)₈ TIM-barrel domain, α/β/α sandwich fold domain, and a C-terminal fibronectin-like domain. The catalytic TIM-barrel domain possessed a catalytic nucleophile (Asp300) and acid/base (Glu524) residues. Interestingly, we found that the cavity of the active site of IpeA was larger than that of other GH3 enzymes, and subsite ?1′ played an important role in its activity. The glucopyranosyl and xylopyranosyl residues of isoprimeverose were located at subsites ?1 and ?1′, respectively. Gln58 and Tyr89 contributed to the interaction with the xylopyranosyl residue of isoprimeverose through hydrogen bonding and stacking effects, respectively. Our findings provide new insights into the substrate recognition of GH3 enzymes.     

Structure of Streptomyces maltosyltransferase GlgE, a homologue of a genetically validated anti-tuberculosis target

GlgE is a recently identified (1→4)-α-d-glucan:phosphate α-d-maltosyltransferase involved in α-glucan biosynthesis in bacteria and is a genetically validated anti-tuberculosis drug target. It is a member of the GH13_3 CAZy subfamily for which no structures were previously known. We have solved the structure of GlgE isoform I from Streptomyces coelicolor and shown that this enzyme has the same catalytic and very similar kinetic properties to GlgE from Mycobacterium tuberculosis. The S. coelicolor enzyme forms a homodimer with each subunit comprising five domains, including a core catalytic α-amylase-type domain A with a (β/α)(8) fold. This domain is elaborated with domain B and two inserts that are specifically configured to define a well conserved donor pocket capable of binding maltose. Domain A, together with domain N from the neighboring subunit, forms a hydrophobic patch that is close to the maltose-binding site and capable of binding cyclodextrins. Cyclodextrins competitively inhibit the binding of maltooligosaccharides to the S. coelicolor enzyme, showing that the hydrophobic patch overlaps with the acceptor binding site. This patch is incompletely conserved in the M. tuberculosis enzyme such that cyclodextrins do not inhibit this enzyme, despite acceptor length specificity being conserved. The crystal structure reveals two further domains, C and S, the latter being a helix bundle not previously reported in GH13 members. The structure provides a framework for understanding how GlgE functions and will help guide the development of inhibitors with therapeutic potential.     

Structural insights into the substrate specificity and function of Escherichia coli K12 YgjK, a glucosidase belonging to the glycoside hydrolase family 63

Proteins belonging to the glycoside hydrolase family 63 (GH63) are found in bacteria, archaea, and eukaryotes. Eukaryotic GH63 proteins are processing α-glucosidase I enzymes that hydrolyze an oligosaccharide precursor of eukaryotic N-linked glycoproteins. In contrast, the functions of the bacterial and archaeal GH63 proteins are unclear. Here we determined the crystal structure of a bacterial GH63 enzyme, Escherichia coli K12 YgjK, at 1.78 Å resolution and investigated some properties of the enzyme. YgjK consists of the N-domain and the A-domain, joined by a linker region. The N-domain is composed of 18 antiparallel β-strands and is classified as a super-β-sandwich. The A-domain contains 16 α-helices, 12 of which form an (α/α)₆-barrel; the remaining 4 α-helices are found in an extra structural unit that we designated as the A′-region. YgjK, a member of the glycoside hydrolase clan GH-G, shares structural similarity with glucoamylase (GH15) and chitobiose phosphorylase (GH65), both of which belong to clan GH-L. In crystal structures of YgjK in complex with glucose, mannose, and galactose, all of the glucose, mannose, and galactose units were located in the catalytic cleft. YgjK showed the highest activity for the α-1,3-glucosidic linkage of nigerose, but also hydrolyzed trehalose, kojibiose, and maltooligosaccharides from maltose to maltoheptaose, although the activities were low. These findings suggest that YgjK is a glucosidase with relaxed specificity for sugars.     

Crystal structures of the apo form of β-fructofuranosidase from Bifidobacterium longum and its complex with fructose

We solved the 1.8 ? crystal structure of β-fructofuranosidase from Bifidobacterium longum KN29.1 - a unique enzyme that allows these probiotic bacteria to function in the human digestive system. The sequence of β-fructofuranosidase classifies it as belonging to the glycoside hydrolase family 32 (GH32). GH32 enzymes show a wide range of substrate specificity and different functions in various organisms. All enzymes from this family share a similar fold, containing two domains: an N-terminal five-bladed β-propeller and a C-terminal β-sandwich module. The active site is located in the centre of the β-propeller domain, in the bottom of a 'funnel'. The binding site, -1, responsible for tight fructose binding, is highly conserved among the GH32 enzymes. Bifidobacterium longum KN29.1 β-fructofuranosidase has a 35-residue elongation of the N-terminus containing a five-turn α-helix, which distinguishes it from the other known members of the GH32 family. This new structural element could be one of the functional modifications of the enzyme that allows the bacteria to act in a human digestive system. We also solved the 1.8 ? crystal structure of the β-fructofuranosidase complex with β-D-fructose, a hydrolysis product obtained by soaking apo crystal in raffinose.