Mechanisms of enzymatic glycoside hydrolysis

The (betaalpha)(8) glycosidases: sequence and structure analyses suggest distant evolutionary relationships

There are currently at least nine distinct glycosidase sequence families which are all known to adopt a TIM barrel fold [Henrissat,B. and Davies,G. (1997) CURR: Opin. Struct. Biol., 7, 637-644]. To explore the relationships between these enzymes and their evolution, comprehensive sequence and structure comparisons were performed, generating four distinct clusters. The first cluster, S1, comprises the alpha-amylase related enzymes, all with the retention mechanism (axial-->axial). The second cluster, S2, included two functional subgroups, one composed of various kinds of glucosidases all with the retention mechanism (equatorial-->equatorial) (the so-called 4/7 superfamily), and the other subgroup including the beta-amylases with the inversion mechanism (axial--> equatorial). The third cluster, S3, with the retention mechanism (equatorial-->equatorial), could be subdivided, based on the catalytic residues and mechanisms, into two functional subgroups: the chitinase group, catalysed by two acidic residues on the C-termini of beta-4 and beta-6, and the hevamine group, using two acidic residues on the C-termini of beta-4 for catalysis. The fourth cluster, S4, is composed of chitobiase with the retention mechanism (equatorial--> equatorial). These clusters are compared with the sequence families derived by Henrissat and coworkers. PSI-BLAST profiles and multiple-alignments of tertiary structures suggest that S1 and S2 are distantly related, as are S3 and S4, which have N-acetylated substrates. This work highlights the difficulties of untangling distant evolutionary relationships in ubiquitous folds such as the TIM barrel.

Identification of the catalytic nucleophile of the Family 31 alpha-glucosidase from Aspergillus niger via trapping of a 5-fluoroglycosyl-enzyme intermediate

The mechanism-based reagent 5-fluoro-alpha-d-glucopyranosyl fluoride (5F alpha GlcF) was used to trap a glycosyl-enzyme intermediate and identify the catalytic nucleophile at the active site of Aspergillus niger alpha-glucosidase (Family 31). Incubation of the enzyme with 5F alpha GlcF, followed by peptic proteolysis and comparative liquid chromatography/MS mapping allowed the isolation of a labelled peptide. Fragmentation analysis of this peptide by tandem MS yielded the sequence WYDMSE, with the label located on the aspartic acid residue (D). Comparison with the known protein sequence identified the labelled amino acid as Asp-224 of the P2 subunit.

Chemical mechanism of beta-xylosidase from Trichoderma reesei QM 9414: pH-dependence of kinetic parameters

The variation of kinetic parameters of beta-xylosidase from Trichoderma reesei QM 9414 with pH was used to elucidate the chemical mechanism of the p-nitrophenyl beta-D-xylopyranoside hydrolysis. The pH-dependence of V and V/K(m) showed that a group on the enzyme with a pK value of 3.20 must be unprotonated and a group with a pK value of 5.20 must be protonated for activity and both are involved in catalysis. Solvent-perturbation studies indicated that these groups are neutral acid type. Temperature dependence of kinetic parameters suggested the stickiness of the substrate at lower temperatures than the optimum and the calculated ionization enthalpies pointed to carboxyl groups as responsible for both pKs. Chemical modification with triethyloxonium tetrafluoroborate and protection with the substrate studies demonstrated essential carboxyl groups on the enzyme. Profiles of pK(i) for D-gluconic acid lactone indicated that a group with a pK value of 3.45 must be protonated for binding and it has been assigned to the carboxyl group of D-gluconic acid formed by lactone ring breakdown in solution.

The crystal structure of Thermotoga maritima maltosyltransferase and its implications for the molecular basis of the novel transfer specificity

Maltosyltransferase (MTase) from the hyperthermophile Thermotoga maritima represents a novel maltodextrin glycosyltransferase acting on starch and malto-oligosaccharides. It catalyzes the transfer of maltosyl units from alpha-1,4-linked glucans or malto-oligosaccharides to other alpha-1,4-linked glucans, malto-oligosaccharides or glucose. It belongs to the glycoside hydrolase family 13, which represents a large group of (beta/alpha)(8) barrel proteins sharing a similar active site structure. The crystal structures of MTase and its complex with maltose have been determined at 2.4 A and 2.1 A resolution, respectively. MTase is a homodimer, each subunit of which consists of four domains, two of which are structurally homologous to those of other family 13 enzymes. The catalytic core domain has the (beta/alpha)(8) barrel fold with the active-site cleft formed at the C-terminal end of the barrel. Substrate binding experiments have led to the location of two distinct maltose-binding sites; one lies in the active-site cleft, covering subsites -2 and -1; the other is located in a pocket adjacent to the active-site cleft. The structure of MTase, together with the conservation of active-site residues among family 13 glycoside hydrolases, are consistent with a common double-displacement catalytic mechanism for this enzyme. Analysis of maltose binding in the active site reveals that the transfer of dextrinyl residues longer than a maltosyl unit is prevented by termination of the active-site cleft after the -2 subsite by the side-chain of Lys151 and the stretch of residues 314-317, providing an explanation for the strict transfer specificity of MTase.

Glycosidase active site mutations in human alpha-L-iduronidase

Mucopolysaccharidosis type I (MPS I; McKusick 25280) results from a deficiency in alpha-L-iduronidase activity. Using a bioinformatics approach, we have previously predicted the putative acid/base catalyst and nucleophile residues in the active site of this human lysosomal glycosidase to be Glu182 and Glu299, respectively. To obtain experimental evidence supporting these predictions, wild-type alpha-L-iduronidase and site-directed mutants E182A and E299A were individually expressed in Chinese hamster ovary-K1 cell lines. We have compared the synthesis, processing, and catalytic properties of the two mutant proteins with wild-type human alpha-L-iduronidase. Both E182A and E299A transfected cells produced catalytically inactive human alpha-L-iduronidase protein at levels comparable to the wild-type control. The E182A protein was synthesized, processed, targeted to the lysosome, and secreted in a similar fashion to wild-type alpha-L-iduronidase. The E299A mutant protein was also synthesized and secreted similarly to the wild-type enzyme, but there were alterations in its rate of traffic and proteolytic processing. These data indicate that the enzymatic inactivity of the E182A and E299A mutants is not due to problems of synthesis/folding, but to the removal of key catalytic residues. In addition, we have identified a MPS I patient with an E182K mutant allele. The E182K mutant protein was expressed in CHO-K1 cells and also found to be enzymatically inactive. Together, these results support the predicted role of E182 and E299 in the catalytic mechanism of alpha-L-iduronidase and we propose that the mutation of either of these residues would contribute to a very severe clinical phenotype in a MPS I patient.

The X-ray structure of Aspergillus aculeatus polygalacturonase and a modeled structure of the polygalacturonase-octagalacturonate complex

Polygalacturonases hydrolyze the alpha-(1-4) glycosidic bonds of de-esterified pectate in the smooth region of the plant cell wall. Crystal structures of polygalacturonase from Aspergillus aculeatus were determined at pH 4.5 and 8.5 both to 2.0 A resolution. A. aculeatus polygalacturonase is a glycoprotein with one N and ten O-glycosylation sites and folds into a right-handed parallel beta-helix. The structures of the three independent molecules are essentially the same, showing no dependency on pH or crystal packing, and are very similar to that of Aspergillus niger polygalacturonase. However, the structures of the long T1 loop containing a catalytic tyrosine residue are significantly different in the two proteins. A three-dimensional model showing the substrate binding mode for a family 28 hydrolase was obtained by a combined approach of flexible docking, molecular dynamics simulations, and energy minimization. The octagalacturonate substrate was modeled as an unbent irregular helix with the -1 ring in a half-chair ((4)H(3)) form that approaches the transition state conformation. A comparative modeling of the three polygalacturonases with known structure shows that six subsites ranging from -4 to +2 are clearly defined but subsites -5 and +3 may or may not be shaped depending on the nearby amino acid residues. Both distal subsites are mostly exposed to the solvent region and have weak binding affinity even if they exist. The complex model provides a clear explanation for the functions, either in catalysis or in substrate binding, of all conserved amino acid residues in the polygalacturonase family of proteins. Modeling suggests that the role of the conserved Asn157 and Tyr270, which had previously been unidentified, may be in transition state stabilization. In A. niger polygalacturonase, the long T1 loop may have to undergo conformational change upon binding of the substrate to bring the tyrosine residue close to subsite -1.

Molecular mimicry of substrate oxygen atoms by water molecules in the beta-amylase active site

Soybean beta-amylase (EC 3.2.1.2) has been crystallized both free and complexed with a variety of ligands. Four water molecules in the free-enzyme catalytic cleft form a multihydrogen-bond network with eight strategic residues involved in enzyme-ligand hydrogen bonds. We show here that the positions of these four water molecules are coincident with the positions of four potential oxygen atoms of the ligands within the complex. Some of these waters are displaced from the active site when the ligands bind to the enzyme. How many are displaced depends on the shape of the ligand. This means that when one of the four positions is not occupied by a ligand oxygen atom, the corresponding water remains. We studied the functional/structural role of these four waters and conclude that their presence means that the conformation of the eight side chains is fixed in all situations (free or complexed enzyme) and preserved from unwanted or forbidden conformational changes that could hamper the catalytic mechanism. The water structure at the active pocket of beta-amylase is therefore essential for providing the ligand recognition process with plasticity. It does not affect the protein active-site geometry and preserves the overall hydrogen-bonding network, irrespective of which ligand is bound to the enzyme. We also investigated whether other enzymes showed a similar role for water. Finally, we discuss the potential use of these results for predicting whether water molecules can mimic ligand atoms in the active center.

Crystal structure of alkaline cellulase K: insight into the alkaline adaptation of an industrial enzyme

The crystal structure of the catalytic domain of alkaline cellulase K was determined at 1.9 A resolution. Because of the most alkaliphilic nature and it's highest activity at pH 9.5, it is used commercially in laundry detergents. An analysis of the structural bases of the alkaliphilic character of the enzyme suggested a mechanism similar to that previously proposed for alkaline proteases, that is, an increase in the number of Arg, His, and Gln residues, and a decrease in Asp and Lys residues. Some ion pairs were formed by the gained Arg residues, which is similar to what has been found in the alkaline proteases. Lys-Asp ion pairs are disfavored and partly replaced with Arg-Asp ion pairs. The alkaline adaptation appeared to be a remodeling of ion pairs so that the charge balance is kept in the high pH range.

Presteady-state kinetics of Bacillus 1,3-1,4-beta-glucanase: binding and hydrolysis of a 4-methylumbelliferyl trisaccharide substrate

In the present study the first stopped-flow experiments performed on Bacillus 1,3-1,4-beta-glucanases are reported. The presteady-state kinetics of the binding of 4-methylumbelliferyl 3-O-beta-cellobiosyl-beta-D-glucoside to the inactive mutant E134A, and the wild-type-catalysed hydrolysis of the same substrate, were studied by measuring changes in the fluorescence of bound substrate or 4-methylumbelliferone produced. The presteady-state traces all showed an initial lag phase followed by a fast monoexponential phase leading to equilibration (for binding to E134A) or to steady state product formation (for the wild-type reaction). The lag phase, with a rate constant of the order of 100 s(-1), was independent of the substrate concentration; apparently an induced-fit mechanism governs the formation of enzyme-substrate complexes. The concentration dependencies of the observed rate constant of the second presteady-state phase were analysed according to a number of reaction models. For the reaction of the wild-type enzyme, it is shown that the fast product formation observed before steady state is not due to a rate-determining deglycosylation step. A model that can explain the observed results involves, in addition to the induced fit, a conformational change of the productive ES complex into a form that binds a second substrate molecule in a non-productive mode.

The determinants of alpha-amylase pH-activity profiles

The glycosyl hydrolases present a large family of enzymes that are of great significance for industry. Consequently, there is considerable interest in engineering the enzymes in this family for optimal performance under a range of very diverse conditions. Until recently, tailoring glycosyl hydrolases for specific industrial processes mainly involved stability engineering, but lately there has also been considerable interest in engineering their pH-activity profiles. We mutated four neutral residues (N190, F290, N326 and Q360) in the chimeric Bacillus Ba2 alpha-amylase to both charged and neutral amino acids. The results show that the pH-activity profile of the Ba2 alpha-amylase can be changed by inserting charged residues close to the active site. The changes in the pH-activity profile for these neutral --> charged mutations do not, however, correlate with the predictions from calculations of the p K(a) values of the active site residues. More surprisingly, the neutral --> neutral mutations change the pH-activity profile as much as the neutral --> charged mutations. From these results, it is concluded that factors other than electrostatics, presumably the dynamic aspects of the active site, are important for the shape of the pH-activity profiles of the alpha-amylases.

Streptomyces matensis laminaripentaose hydrolase is an 'inverting' beta-1,3-glucanase

The laminaripentaose-producing beta-1,3-glucanase of Streptomyces matensis is a member of the glycoside hydrolase family GH-64. We have constructed and purified a recombinant hexahistidine-tagged form of the enzyme for characterisation. The enzyme, which exists as a monomer in solution, hydrolyses beta-1,3-glucan by a mechanism leading to overall inversion of the anomeric configuration. This is the first determination of the mechanism prevailing in glycoside hydrolase family GH-64 and this is the first characterisation of an 'inverting' beta-1,3-glucanase.

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

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

Directed evolution of new glycosynthases from Agrobacterium β-glucosidase: a general screen to detect enzymes for oligosaccharide synthesis

BACKGROUND

Oligosaccharide synthesis is becoming increasingly important to industry as diverse therapeutic roles for these molecules are discovered. The chemical synthesis of oligosaccharides on an industrial scale is often prohibitively complex and costly. An alternative, that of enzymatic synthesis, is limited by the difficulty of obtaining an appropriate enzyme. A general screen for enzymes that catalyze the synthesis of the glycosidic bond would enable the identification and engineering of new or improved enzymes.

RESULTS

Glycosynthases are nucleophile mutants of retaining glycosidases that efficiently catalyze the synthesis of the glycosidic linkage by condensing an activated glycosyl fluoride donor with a suitable acceptor sugar. A novel agar plate-based coupled-enzyme screen was developed (using a two-plasmid system) and used to select an improved glycosynthase from a library of mutants.

CONCLUSIONS

Plate-based coupled-enzyme screens of this type are extremely valuable for identification of functional synthetic enzymes and can be applied to the evolution of a range of glycosyl transferases.

The X-ray crystal structure of the Trichoderma reesei family 12 endoglucanase 3, Cel12A, at 1.9 A resolution

We present the three-dimensional structure of Trichoderma reesei endoglucanase 3 (Cel12A), a small, 218 amino acid residue (24.5 kDa), neutral pI, glycoside hydrolase family 12 cellulase that lacks a cellulose-binding module. The structure has been determined using X-ray crystallography and refined to 1.9 A resolution. The asymmetric unit consists of six non-crystallographic symmetry-related molecules that were exploited to improve initial multiple isomorphous replacement phasing, and subsequent structure refinement. The enzyme contains one disulfide bridge and is glycosylated at Asp164 by a single N-acetyl glucosamine residue. The protein has the expected fold for a glycoside hydrolase clan-C family 12 enzyme. It contains two beta-sheets, of six and nine strands, packed on top of one another, and one alpha-helix. The concave surface of the nine-stranded beta-sheet forms a large substrate-binding groove in which the active-site residues are located. In the active site, we find a carboxylic acid trio, similar to that of glycoside hydrolase families 7 and 16. The strictly conserved Asp99 hydrogen bonds to the nucleophile, the invariant Glu116. The binding crevice is lined with both aromatic and polar amino acid side-chains which may play a role in substrate binding. The structure of the fungal family 12 enzyme presented here allows a complete structural characterization of the glycoside hydrolase-C clan.

Pectate lyase 10A from Pseudomonas cellulosa is a modular enzyme containing a family 2a carbohydrate-binding module

Pectate lyase 10A (Pel10A) enzyme from Pseudomonas cellulosa is composed of 649 residues and has a molecular mass of 68.5 kDa. Sequence analysis revealed that Pel10A contained a signal peptide and two serine-rich linker sequences that separate three modules. Sequence similarity was seen between the 9.2 kDa N-terminal module of Pel10A and family 2a carbohydrate-binding modules (CBMs). This N-terminal module of Pel10A was shown to encode an independently functional module with affinity to crystalline cellulose. A high sequence identity of 66% was seen between the 14.2 kDa central module of Pel10A and the functionally uncharacterized central modules of the xylan-degrading enzymes endoxylanase 10B, arabinofuranosidase 62C and esterase 1D, also from P. cellulosa. The 35.8 kDa C-terminal module of Pel10A was shown to have 30 and 36% identities with the family 10 pectate lyases from Azospirillum irakense and an alkaliphilic strain of Bacillus sp. strain KSM-P15, respectively. This His-tagged C-terminal module of the Pel10A was shown to encode an independent catalytic module (Pel10Acm). Pel10Acm was shown to cleave pectate and pectin in an endo-fashion and to have optimal activity at pH 10 and in the presence of 2 mM Ca2+. Highest enzyme activity was detected at 62 degrees C. Pel10Acm was shown to be most active against pectate (i.e. polygalacturonic acid) with progressively less activity against 31, 67 and 89% esterified citrus pectins. These data suggest that Pel10A has a preference for sequences of non-esterified galacturonic acid residues. Significantly, Pel10A and the P. cellulosa rhamnogalacturonan lyase 11A, in the accompanying article [McKie, Vincken, Voragen, van den Broek, Stimson and Gilbert (2001) Biochem. J. 355, 167-177], are the first CBM-containing pectinases described to date.

Crystallographic evidence for substrate-assisted catalysis in a bacterial beta-hexosaminidase

beta-Hexosaminidase, a family 20 glycosyl hydrolase, catalyzes the removal of beta-1,4-linked N-acetylhexosamine residues from oligosaccharides and their conjugates. Heritable deficiency of this enzyme results in various forms of GalNAc-beta(1,4)-[N-acetylneuraminic acid (2,3)]-Gal-beta(1,4)-Glc-ceramide gangliosidosis, including Tay-Sachs disease. We have determined the x-ray crystal structure of a beta-hexosaminidase from Streptomyces plicatus to 2.2 A resolution (Protein Data Bank code ). beta-Hexosaminidases are believed to use a substrate-assisted catalytic mechanism that generates a cyclic oxazolinium ion intermediate. We have solved and refined a complex between the cyclic intermediate analogue N-acetylglucosamine-thiazoline and beta-hexosaminidase from S. plicatus to 2.1 A resolution (Protein Data Bank code ). Difference Fourier analysis revealed the pyranose ring of N-acetylglucosamine-thiazoline bound in the enzyme active site with a conformation close to that of a (4)C(1) chair. A tryptophan-lined hydrophobic pocket envelopes the thiazoline ring, protecting it from solvolysis at the iminium ion carbon. Within this pocket, Tyr(393) and Asp(313) appear important for positioning the 2-acetamido group of the substrate for nucleophilic attack at the anomeric center and for dispersing the positive charge distributed into the oxazolinium ring upon cyclization. This complex provides decisive structural evidence for substrate-assisted catalysis and the formation of a covalent, cyclic intermediate in family 20 beta-hexosaminidases.

Recent progress in the biology, chemistry and structural biology of DNA glycosylases

Since the discovery in 1974 of uracil DNA glycosylase (UDG), the first member of the family of enzymes involved in base excision repair (BER), considerable progress has been made in the understanding of DNA glycosylases, the polypeptides that remove damaged or mispaired DNA bases from DNA. We also know the enzymes that act downstream of the glycosylases, in the processing of abasic sites, in gap filling and in DNA ligation. This article covers the most recent developments in our understanding of BER, with particular emphasis on the mechanistic aspects of this process, which have been made possible by the elucidation of the crystal structures of several glycosylases in complex with their respective substrates, substrate analogues and products. The biological importance of individual BER pathways is also being appreciated through the inactivation of key BER genes in knockout mouse models.

Structural and functional comparison of polysaccharide-degrading enzymes

Sugar molecules as well as enzymes degrading them are ubiquitously present in physiological systems, especially for vertebrates. Polysaccharides have at least two aspects to their function, one due to their mechanical properties and the second one involves multiple regulatory processes or interactions between molecules, cells, or extracellular space. Various bacteria exert exogenous pressures on their host organism to diversity glycans and their structures in order for the host organism to evade the destructive function of such microbes. Many bacterial organism produce glycan-degrading enzymes in order to facilitate their invasion of host tissues. Such polysaccharide degrading enzymes utilize mainly two modes of polysaccharide-degradation, a hydrolysis and a beta-elimination process. The three-dimensional structures of several of these enzymes have been elucidated recently using X-ray crystallography. There are many common structural motifs among these enzymes, mainly the presence of an elongated cleft transversing these molecules which functions as a polysaccharide substrate binding site as well as the catalytic site for these enzymes. The detailed structural information obtained about these enzymes allowed formulation of proposed mechanisms of their action. The polysaccharide lyases utilize a proton acceptance and donation mechanism (PAD), whereas polysaccharide hydrolases use a direct double displacement (DD) mechanism to degrade their substrates.

Mechanism of porcine pancreatic alpha-amylase. Inhibition of amylose and maltopentaose hydrolysis by alpha-, beta- and gamma-cyclodextrins

The effects of alpha-, beta- and gamma-cyclodextrins on the amylose and maltopentaose hydrolysis catalysed by porcine pancreatic alpha-amylase (PPA) were investigated. The results of the statistical analysis performed on the kinetic data using the general initial velocity equation of a one-substrate reaction in the presence of one inhibitor indicate that the type of inhibition involved depends on the substrate used: the inhibition of amylose hydrolysis by alpha-, beta- and gamma-cyclodextrin is of the competitive type, while the inhibition of maltopentaose hydrolysis is of the mixed noncompetitive type. Consistently, the Lineweaver-Burk plots intersect on the vertical axis when amylose is used as the substrate, while in the case of maltopentaose, the intersection occurs at a point located in the second quadrant. The inhibition of the hydrolysis therefore involves only one abortive complex, PPA-cyclodextrin, when amylose is used as the substrate, while two abortive complexes, PPA-cyclodextrin and PPA-maltopentaose-cyclodextrin, are involved with maltopentaose. The mixed noncompetitive inhibition thus shows the existence of one accessory binding site. In any case, only one molecule of inhibitor binds to PPA. In line with these findings, the difference spectra of PPA produced by alpha-, beta- and gamma-cyclodextrin indicate that binding occurs at a tryptophan and a tyrosine residue. The corresponding dissociation constants and the inhibition constants obtained using the kinetic approach are in the same range (1.2-7 mM). The results obtained here on the inhibition of maltopentaose hydrolysis by cyclodextrin are similar to those previously obtained with acarbose as the inhibitor [Alkazaz, M., Desseaux, V., Marchis-Mouren, G., Prodanov, E. & Santimone, M. (1998) Eur. J. Biochem. 252, 100-107], but differ from those obtained with amylose as the substrate and acarbose as inhibitor [Alkazaz, M., Desseaux, V., Marchis-Mouren, G., Payan, F., Forest, E. & Santimone, M. (1996) Eur. J. Biochem. 241, 787-796]. It is concluded that the hydrolysis of both long and short chain substrates requires at least one secondary binding site, including a tryptophan residue.

Identification of essential active-site residues in the cyanogenic beta-glucosidase (linamarase) from cassava (Manihot esculenta Crantz) by site-directed mutagenesis

The coding sequence of the mature cyanogenic beta-glucosidase (beta-glucoside glucohydrolase, EC 3.2.1.21; linamarase) was cloned into the vector pYX243 modified to contain the SUC2 yeast secretion signal sequence and expressed in Saccharomyces cerevisiae. The recombinant enzyme is active, glycosylated and showed similar stability to the plant protein. Michaelis constants for hydrolysis of the natural substrate, linamarin (K(m)=1.06 mM) and the synthetic p-nitrophenyl beta-D-glucopyranoside (PNP-Glc; K(m)=0.36 mM), as well as apparent pK(a) values of the free enzyme and the enzyme-substrate complexes (pK(E)(1)=4.4-4.8, pK(E)(2)=6.7-7.2, pK(ES)(1)=3.9-4.4, pK(ES)(2)=8.3) were very similar to those of the plant enzyme. Site-directed mutagenesis was carried out to study the function of active-site residues based on a homology model generated for the enzyme using the MODELLER program. Changing Glu-413 to Gly destroyed enzyme activity, consistent with it being the catalytic nucleophile. The Gln-339Glu mutation also abolished activity, confirming a function in positioning the catalytic diad. The Ala-201Val mutation shifted the pK(a) of the acid/base catalyst Glu-198 from 7.22 to 7.44, reflecting a change in its hydrophobic environment. A Phe-269Asn change increased K(m) for linamarin hydrolysis 16-fold (16.1 mM) and that for PNP-Glc only 2.5-fold (0.84 mM), demonstrating that Phe-269 contributes to the cyanogenic specificity of the cassava beta-glucosidase.

Identification of residues involved in catalytic activity of the inverting glycosyl transferase WbbE from Salmonella enterica serovar borreze

Synthesis of the O:54 O antigen of Salmonella enterica is initiated by the nonprocessive glycosyl transferase WbbE, assigned to family 2 of the glycosyl transferase enzymes (GT2). GT2 enzymes possess a characteristic N-terminal domain, domain A. Based on structural data from the GT2 representative SpsA (S. J. Charnock and G. J. Davies, Biochemistry 38:6380-6385, 1999), this domain is responsible for nucleotide binding. It possesses two invariant Asp residues, the first forming a hydrogen bond to uracil and the second coordinating a Mn(2+) ion. Site-directed replacement of Asp41 (D41A) of WbbE, the analogue of the first Asp residue of SpsA, revealed that this is not required for activity. WbbE possesses three Asp residues near the position analogous to the second conserved residue. Whereas D95A reduced WbbE activity, activity in D93A and D96A mutants was abrogated, suggesting that either D93 or D96 may coordinate the Mn(2+) ion. Our studies also identified a C-terminal region of sequence conservation in 22 GT2 members, including WbbE. SpsA was not among these. This region is characterized by an ED(Y) motif. The Glu and Asp residues of this motif were individually replaced in WbbE. E180D in WbbE had greatly reduced activity, and an E180Q replacement completely abrogated activity; however, D181E had no effect. E180 is predicted to reside on a turn. Combined with the alignment of the motif with potential catalytic residues in the GT2 enzymes ExoM and SpsA, we speculate that E180 is the catalytic residue of WbbE. Sequence and predicted structural divergence in the catalytic region of GT2 members suggests that this is not a homogeneous family.

beta-fructosidase superfamily: homology with some alpha-L-arabinases and beta-D-xylosidases

Comparison of the amino acid sequences of four families of glycosyl hydrolases reveals that they are homologous and have several common conserved regions. Two of these families contain beta-fructosidases (glycosyl hydrolase families GH32 and GH68) and the other two include alpha-L-arabinases and beta-xylosidases (families GH43 and GH62). The latter two families are proposed to be grouped together with the former two into the beta-fructosidase (furanosidase) superfamily. Several ORFs can be considered as a fifth family of the superfamily on the basis of sequence similarity. It is shown for the first time that a glycosyl hydrolase superfamily can include enzymes with both inversion and retention mechanism of action. Composition of the active center for enzymes of the superfamily is discussed.

Glucoamylase: structure/function relationships, and protein engineering

Glucoamylases are inverting exo-acting starch hydrolases releasing beta-glucose from the non-reducing ends of starch and related substrates. The majority of glucoamylases are multidomain enzymes consisting of a catalytic domain connected to a starch-binding domain by an O-glycosylated linker region. Three-dimensional structures have been determined of free and inhibitor complexed glucoamylases from Aspergillus awamori var. X100, Aspergillus niger, and Saccharomycopsis fibuligera. The catalytic domain folds as a twisted (alpha/alpha)(6)-barrel with a central funnel-shaped active site, while the starch-binding domain folds as an antiparallel beta-barrel and has two binding sites for starch or beta-cyclodextrin. Certain glucoamylases are widely applied industrially in the manufacture of glucose and fructose syrups. For more than a decade mutational investigations of glucoamylase have addressed fundamental structure/function relationships in the binding and catalytic mechanisms. In parallel, issues of relevance for application have been pursued using protein engineering to improve the industrial properties. The present review focuses on recent findings on the catalytic site, mechanism of action, substrate recognition, the linker region, the multidomain architecture, the engineering of specificity and stability, and roles of individual substrate binding subsites.

Protein engineering of bacterial alpha-amylases

alpha-Amylases constitute a very diverse family of glycosyl hydrolases that cleave alpha1-->4 linkages in amylose and related polymers. Recent structural and mutagenic studies of archeael, mammalian and bacterial alpha-amylases have resulted in a wealth of information on the catalytic mechanism and on the structural features of this enzyme class. Because of their high thermo-stability, the Bacillus alpha-amylases have found widespread use in industrial processes, and much attention has been devoted to optimising these enzymes for the very harsh conditions encountered there. Stability has been a major area of focus in this respect, and several remarkably stable bacterial alpha-amylases have been produced by bioengineering techniques. Protein engineering studies of pH-activity profiles and of substrate specificities have also been initiated, although without much success. In the coming years it is likely, however, that the focus of alpha-amylase engineering will shift from engineering stability to these new areas.

Bacterial 1,3-1,4-beta-glucanases: structure, function and protein engineering

1,3-1,4-beta-Glucanases (or lichenases, EC 3.2.1.73) hydrolyse linear beta-glucans containing beta-1,3 and beta-1,4 linkages such as cereal beta-glucans and lichenan, with a strict cleavage specificity for beta-1,4 glycosidic bonds on 3-O-substituted glucosyl residues. The bacterial enzymes are retaining glycosyl hydrolases of family 16 with a jellyroll beta-sandwich fold and a substrate binding cleft composed of six subsites. The present paper reviews the structure-function aspects of the enzymatic action including mechanistic enzymology, protein engineering and X-ray crystallographic studies.

High resolution X-ray crystallography shows that ascorbate is a cofactor for myrosinase and substitutes for the function of the catalytic base

Myrosinase, an S-glycosidase, hydrolyzes plant anionic 1-thio-beta-d-glucosides (glucosinolates) considered part of the plant defense system. Although O-glycosidases are ubiquitous, myrosinase is the only known S-glycosidase. Its active site is very similar to that of retaining O-glycosidases, but one of the catalytic residues in O-glycosidases, a carboxylate residue functioning as the general base, is replaced by a glutamine residue. Myrosinase is strongly activated by ascorbic acid. Several binary and ternary complexes of myrosinase with different transition state analogues and ascorbic acid have been analyzed at high resolution by x-ray crystallography along with a 2-deoxy-2-fluoro-glucosyl enzyme intermediate. One of the inhibitors, d-gluconhydroximo-1,5-lactam, binds simultaneously with a sulfate ion to form a mimic of the enzyme-substrate complex. Ascorbate binds to a site distinct from the glucose binding site but overlapping with the aglycon binding site, suggesting that activation occurs at the second step of catalysis, i.e. hydrolysis of the glycosyl enzyme. A water molecule is placed perfectly for activation by ascorbate and for nucleophilic attack on the covalently trapped 2-fluoro-glucosyl-moiety. Activation of the hydrolysis of the glucosyl enzyme intermediate is further evidenced by the observation that ascorbate enhances the rate of reactivation of the 2-fluoro-glycosyl enzyme, leading to the conclusion that ascorbic acid substitutes for the catalytic base in myrosinase.

Distributions of structural features contributing to thermostability in mesophilic and thermophilic alpha/beta barrel glycosyl hydrolases

Analysis of the structural basis for thermostability in proteins has come mainly from pairwise comparisons of mesophilic and thermophilic structures and has often yielded conflicting results. Interpretation of these results would be enhanced by knowing the normal range of features found for mesophilic proteins. In order to provide the average and distribution values of structural features among similar mesophilic proteins, we compared the amino acid composition, solvent accessible surface area, hydrogen bonds, number of ion pairs, and thermal factors of 22 structures of alpha/beta barrel glycosyl hydrolases. These distributions are then compared to values from seven alpha/beta barrel glycosyl hydrolases from thermophilic organisms. We find that the distribution of each structural feature is broad within the mesophilic proteins and illustrates the difficulty of making pairwise comparisons of mesophiles to thermophiles where differences for individual proteins may be within the normal range for the group. In comparing mesophiles to thermophiles as a group, we find that thermophilic structures have fewer glycines in a particular region of the structure and higher thermal factors at room temperature. These results suggest the basis for thermostability may be related to protein motion rather than to static features of protein structure.

Identification of Asp197 as the catalytic nucleophile in the family 38 alpha-mannosidase from bovine kidney lysosomes

Bovine kidney lysosomal alpha-mannosidase is a family 38 alpha-mannosidase involved in the degradation of glycoproteins. The mechanism-based reagent, 5-fluoro-beta-L-gulosyl fluoride, was used to trap a glycosyl-enzyme intermediate, thereby labelling the catalytic nucleophile of this enzyme. After proteolytic digestion and high performance liquid chromatography/tandem mass spectrometry (MS) analysis, a labelled peptide was localised, and the sequence: HIDPFGHSRE determined by fragmentation tandem MS analysis. Taking into consideration sequence alignments of this region with those of other alpha-mannosidases of the same family, this result strongly suggests that the catalytic nucleophile in this enzyme is Asp197.

iota-Carrageenases constitute a novel family of glycoside hydrolases, unrelated to that of kappa-carrageenases

iota-Carrageenases are polysaccharide hydrolases that cleave the beta-1,4 linkages between the d-galactose-4-sulfate and 3, 6-anhydro-d-galactose-2-sulfate residues in the red algal galactans known as iota-carrageenans. We report here on the purification of iota-carrageenase activity from the marine bacterium Zobellia galactanovorans and on the characterization of iota-carrageenase structural genes. Genomic libraries from this latter bacterium as well as from Alteromonas fortis were functionally screened for the presence of iota-carrageenase(+) clones. The Z. galactanovorans and A. fortis iota-carrageenase genes encode homologous proteins of 53.4 and 54.8 kDa, respectively. Based on hydrophobic cluster analysis and on the (1)H NMR monitoring of the products of the overexpressed A. fortis iota-carrageenase, these enzymes appear to form a new family of glycoside hydrolases, unrelated to that of kappa-carrageenases and with an inverting mechanism of hydrolysis. They both feature a 45-amino acid-long N-terminal segment with sequence similarity to the N-terminal region of several other polysaccharidases. In those for which a three-dimensional structure is available, this conspicuous segment, also deemed "glycanase motif" (Chua, J. E. H., Manning, P. A., and Morona, R. (1999) Microbiology (Reading) 145, 1649-1659), corresponds to a strand-helix-strand "cap" that covers the N-terminal end of a common, right-handed beta-helical fold.

Comparative modeling of the three-dimensional structures of family 3 glycoside hydrolases

There are approximately 100 known members of the family 3 group of glycoside hydrolases, most of which are classified as beta-glucosidases and originate from microorganisms. The only family 3 glycoside hydrolase for which a three-dimensional structure is available is a beta-glucan exohydrolase from barley. The structural coordinates of the barley enzyme is used here to model representatives from distinct phylogenetic clusters within the family. The majority of family 3 hydrolases have an NH(2)-terminal (alpha/beta)(8) barrel connected by a short linker to a second domain, which adopts an (alpha/beta)(6) sandwich fold. In two bacterial beta-glucosidases, the order of the domains is reversed. The catalytic nucleophile, equivalent to D285 of the barley beta-glucan exohydrolase, is absolutely conserved across the family. It is located on domain 1, in a shallow site pocket near the interface of the domains. The likely catalytic acid in the barley enzyme, E491, is on domain 2. Although similarly positioned acidic residues are present in closely related members of the family, the equivalent amino acid in more distantly related members is either too far from the active site or absent. In the latter cases, the role of catalytic acid is probably assumed by other acidic amino acids from domain 1.

Crystal structure of hyaluronidase, a major allergen of bee venom

BACKGROUND

Hyaluronic acid (HA) is the most abundant glycosaminoglycan of vertebrate extracellular spaces and is specifically degraded by a beta-1,4 glycosidase. Bee venom hyaluronidase (Hya) shares 30% sequence identity with human hyaluronidases, which are involved in fertilization and the turnover of HA. On the basis of sequence similarity, mammalian enzymes and Hya are assigned to glycosidase family 56 for which no structure has been reported yet.

RESULTS

The crystal structure of recombinant (Baculovirus) Hya was determined at 1.6 A resolution. The overall topology resembles a classical (beta/alpha)(8) TIM barrel except that the barrel is composed of only seven strands. A long substrate binding groove extends across the C-terminal end of the barrel. Cocrystallization with a substrate analog revealed the presence of a HA tetramer bound to subsites -4 to -1 and distortion of the -1 sugar.

CONCLUSIONS

The structure of the complex strongly suggest an acid-base catalytic mechanism, in which Glu113 acts as the proton donor and the N-acetyl group of the substrate is the nucleophile. The location of the catalytic residues shows striking similarity to bacterial chitinase which also operates via a substrate-assisted mechanism.

Identification of essential amino acid residues in the Sinorhizobium meliloti glucosyltransferase ExoM

ExoM is a beta(1-4)-glucosyltransferase involved in the assembly of the repeat unit of the exopolysaccharide succinoglycan from Sinorhizobium meliloti. By comparing the sequence of ExoM to those of other members of the Pfam Glyco Domain 2 family, most notably SpsA (Bacillus subtilis) for whom the three-dimensional structure has been resolved, three potentially important aspartic acid residues of ExoM were identified. Single substitutions of each of the Asp amino acids at positions 44, 96, and 187 with Ala resulted in the loss of mutant recombinant protein activity in vitro as well as the loss of succinoglycan production in an in vivo rescue assay. Mutants harboring Glu instead of Asp-44 or Asp-96 possessed no in vitro activity but could restore succinoglycan production in vivo. However, replacement of Asp-187 with Glu completely inactivated ExoM as judged by both the in vitro and in vivo assays. These results indicate that Asp-44, Asp-96, and Asp-187 are essential for the activity of ExoM. Furthermore, these data are consistent with the functions proposed for each of the analogous aspartic acids of SpsA based on the SpsA-UDP structure, namely, that Asp-44 and Asp-96 are involved in UDP substrate binding and that Asp-187 is the catalytic base in the glycosyltransferase reaction.

Glycosidase mechanisms

Insights into glycosidase mechanisms have come from X-ray crystallographic studies on complexes with substrate analogs and inhibitors, representing all the intermediate species along the reaction coordinate. Site-directed mutagenesis continues to play a significant role in understanding mechanisms, but is also proving important in generating glycosidases of modified mechanism or specificity.

Increased thermal resistance and modification of the catalytic properties of a beta-glucosidase by random mutagenesis and in vitro recombination

The bglB gene from Paenibacillus polymyxa was subjected to random mutagenesis mediated by error prone polymerase chain reaction amplification and DNA shuffling. After this treatment, mutant variants of the encoded beta-glucosidase with enhanced thermal resistance were selected. We identified five amino acid substitutions at four different positions of the sequence that increased the resistance of the enzyme to heat denaturation. Four of the mutations, H62R, M319V, M319I, and M361I, did not change the kinetic parameters of the enzyme. However, mutant N223Y, which caused only a marginal increase in thermoresistance, showed an 8-fold decrease in K(m). Copies of the bglB gene carrying each one of the individual mutations were recombined in vitro by DNA shuffling. As a result, we obtained an enzyme that simultaneously exhibited a 20-fold increase in heat resistance and an 8-fold increase in the catalytic efficiency. The structural basis of the properties conferred by the mutations was analyzed using homology-based structural models. The four mutations causing a more pronounced effect on thermoresistance were located in loops, on the periphery of the (alpha/beta)(8) barrel that conforms the structure of the protein. Mutation N223Y, which modifies the catalytic properties of the enzyme, was on one of the barrel beta-strands that shape the active center.

Synthesis and enzymatic evaluation of five-membered iminocyclitols and a pseudodisaccharide

Described here are the synthesis of five-membered iminocyclitols with galacto-configuration and a pseudodisaccharide, and their inhibitory activities against beta-galactosyltransferase, beta-galactosidase and alpha-mannosidase.

Classification of chitinases modules

Chitinases frequently display a modular structure featuring a catalytic domain attached to one or several ancillary noncatalytic domains whose function is often chitin binding. Gene cloning and DNA sequencing have allowed the determination of a massive number of amino acid sequences of chitinases during the last 10 years. This chapter presents a unifying classification system of the various chitinase modules that combines specific features of their sequences, three-dimensional structures and reaction mechanisms.

Substrate specificity in glycoside hydrolase family 10. Structural and kinetic analysis of the Streptomyces lividans xylanase 10A

Endoxylanases are a group of enzymes that hydrolyze the beta-1, 4-linked xylose backbone of xylans. They are predominantly found in two discrete sequence families known as glycoside hydrolase families 10 and 11. The Streptomyces lividans xylanase Xyl10A is a family 10 enzyme, the native structure of which has previously been determined by x-ray crystallography at a 2.6 A resolution (Derewenda, U., Swenson, L., Green, R., Wei, Y., Morosoli, R., Shareck, F., Kluepfel, D., and Derewenda, Z. S. (1994) J. Biol. Chem. 269, 20811-20814). Here, we report the native structure of Xyl10A refined at a resolution of 1.2 A, which reveals many features such as the rare occurrence of a discretely disordered disulfide bond between residues Cys-168 and Cys-201. In order to investigate substrate binding and specificity in glycoside hydrolase family 10, the covalent xylobiosyl enzyme and the covalent cellobiosyl enzyme intermediates of Xyl10A were trapped through the use of appropriate 2-fluoroglycosides. The alpha-linked intermediate with the nucleophile, Glu-236, is in a (4)C(1) chair conformation as previously observed in the family 10 enzyme Cex from Cellulomonas fimi (Notenboom, V., Birsan, C., Warren, R. A. J., Withers, S. G., and Rose, D. R. (1998) Biochemistry 37, 4751-4758). The different interactions of Xyl10A with the xylobiosyl and cellobiosyl moieties, notably conformational changes in the -2 and -1 subsites, together with the observed kinetics on a range of aryl glycosides, shed new light on substrate specificity in glycoside hydrolase family 10.

pH-dependence of the fast step of maltose hydrolysis catalysed by glucoamylase G1 from Aspergillus niger

The presteady-state kinetic parameters of the interaction ofwild-type glucoamylase from Aspergillus niger (EC 3.2.1.3)with maltose were obtained and analysed in the pH range 3-7 withintervals of 0.25 pH units. In all cases the following three-step reaction scheme was found to apply. [Equation: see text]. The general result of the analysis of the presteady-state kinetics is that glucoamylase G1 is affected by the protonation states of three groups, with pK(a) values of 2.7, 4.5 and 5.7 in the free enzyme and of 2.7, 4.75 and 6.5 in the first enzyme-substrate complex. The protonation of the group in the enzyme-substrate complex with a pK(a) 6.5 hadno effect on k(2) (1640 s(-1)) or k(-2) (20+/-4 s(-1)), but resulted in a stronger enzyme-substrate interaction, due to a decrease of K(1) from 40 to 6.3 mM. In other words,when the substrate is bound, the pK(a) of the acidgroup changes to increase the fraction of reactive enzyme. Since this pK(a) parallels that of the Michaelis complex, known from the pH-dependence of k(cat), the group in question is most probably the catalytic acid Glu-179. Protonation of Glu-179 thus is of no importance in the second step, clearly indicating that this step represents a conformational change and not the actual hydrolysis step of the reaction. Protonation of the pK(a)=4.75 group leads to a small decrease in k(2) to 1090 s(-1), and also to minor changes in K(1). The group with pK(a)=2.7 leads toa major decrease of k(2), of which the limit may bezero, but shows no effect on K(1). Thus no differenceis seen between the pK(a) values of the free enzymeand of the first enzyme-substrate complex at low pH.

Mutagenesis of glycosidases

Enzymatic hydrolysis of glycosides can occur by one of two elementary mechanisms identified by the stereochemical outcome of the reaction, inversion or retention. The key active-site residues involved are a pair of carboxylic acids in each case, and strategies for their identification and for probing the details of their roles in catalysis have been developed through detailed kinetic analysis of mutants. Similarly the roles of other active-site residues have also been probed this way, and mutants have been developed that trap intermediates in catalysis, allowing the determination of the three-dimensional structures of several such key species. By manipulating the locations or even the presence of these carboxyl side chains in the active site, the mechanisms of several glycosidases have been completely changed, and this has allowed the development of "glycosynthases," mutant glycosidases that are capable of synthesizing oligosaccharides but unable to degrade them. Surprisingly little progress has been made on altering specificities through mutagenesis, although recent results suggest that gene shuffling coupled with effective screens will provide the most effective approach.