Alternative strategy for converting an inverting glycoside hydrolase into a glycosynthase

The tyrosine residue Y198 is known to support a nucleophilic water molecule with the general base residue, D263, in the reducing-end xylose-releasing exo-oligoxylanase (Rex). A mutation in the tyrosine residue changing it into phenylalanine caused a drastic decrease in the hydrolytic activity and a small increase in the F(-) releasing activity from alpha-xylobiosyl fluoride in the presence of xylose. In contrast, mutations at D263 resulted in the decreased F(-) releasing activity. As a result of the high F(-) releasing activity and low hydrolytic activity, Y198F of Rex accumulates a large amount of product during the glycosynthase reaction. We propose a novel method for producing a glycosynthase from an inverting glycoside hydrolase by mutating a residue that holds the nucleophilic water molecule with the general base residue while keeping the general base residue intact.     

Characterization of glycosynthase mutants derived from glycoside hydrolase family 10 xylanases

Four xylanases belonging to glycoside hydrolase family 10-Thermotoga maritima XylB (TM), Clostridium stercorarium XynB (CS), Bacillus halodurans XynA (BH), and Cellulomonas fimi Cex (CF)-were converted to glycosynthases by substituting the nucleophilic glutamic acid residues with glycine, alanine, and serine. The glycine mutants exhibited the highest levels of glycosynthase activity with all four enzymes. All the glycine mutants formed polymeric beta-1,4-linked xylopyranose as a precipitate during reaction with alpha-xylobiosyl fluoride. Two glycine mutants (TM and CF) recognized X(2) as an effective acceptor molecule to prohibit the formation of the polymer, while the other two (CS and BH) did not. The difference in acceptor specificity is considered to reflect the difference in substrate affinity at their +2 subsites. The results agreed with the structural predictions of the subsite, where TM and CF exhibit high affinity at subsite 2, suggesting that the glycosynthase technique is useful for investigating the affinity of +subsites.     

1,2-alpha-l-Fucosynthase: a glycosynthase derived from an inverting alpha-glycosidase with an unusual reaction mechanism

Fucosyloligosaccharides have great therapeutic potential. Here we present a new route for synthesizing a Fucalpha1,2Gal linkage by introducing glycosynthase technology into 1,2-alpha-l-fucosidase. The enzyme adopts a unique reaction mechanism, in which asparagine-423 activated by aspartic acid-766 acts as a base while asparagine-421 fixes both a catalytic water and glutamic acid-566 (an acid) in the proper orientations. Glycosynthase activity of N421G, N423G, and D766G mutants was examined using beta-fucosyl fluoride and lactose, and among them, the D766G mutant most effectively synthesized 2'-fucosyllactose. 1,2-alpha-l-Fucosynthase is the first glycosynthase derived from an inverting alpha-glycosidase and from a glycosidase with an unusual reaction mechanism.     

Catalytic role of the calcium ion in GH97 inverting glycoside hydrolase

The role of calcium ion in the active site of the inverting glycoside hydrolase family 97 enzyme, BtGH97a, was investigated through structural and kinetic studies. The calcium ion was likely directly involved in the catalytic reaction. The pH dependence of k_cat/K_m values in the presence or absence of calcium ion indicated that the calcium ion lowered the pK_a of the base catalyst. The significant decreases in k_cat/K_m for hydrolysis of substrates with basic leaving groups in the absence of calcium ion confirmed that the calcium ion facilitated the leaving group departure.     

The first α-1,3-glucosidase from bacterial origin belonging to glycoside hydrolase family 31

Genome analysis of Lactobacillus johnsonii NCC533 has been recently completed. One of its annotated genes, lj0569, encodes the protein having the conserved domain of glycoside hydrolase family 31. Its homolog gene (ljag31) in L. johnsonii NBRC13952 was cloned and expressed using an Escherichia coli expression system, resulting in poor production of recombinant LJAG31 protein due to inclusion body formation. Production of soluble recombinant LJAG31 was improved with high concentration of NaCl in medium, possible endogenous chaperone induction by benzyl alcohol, and over-expression of GroES–GroEL chaperones. Recombinant LJAG31 was an α-glucosidase with broad substrate specificity toward both homogeneous and heterogeneous substrates. This enzyme displayed higher specificity (in terms of k_cat/K_m) toward nigerose, maltulose, and kojibiose than other natural substrates having an α-glucosidic linkage at the non-reducing end, which suggests that these sugars are candidates for prebiotics contributing to the growth of L. johnsonii. To our knowledge, LJAG31 is the first bacterial α-1,3-glucosidase to be characterized with a high k_cat/K_m value for nigerose [α-d-Glcp-(1 → 3)-d-Glcp]. Transglucosylation of 4-nitrophenyl α-d-glucopyranoside produced two 4-nitrophenyl disaccharides (4-nitrophenyl α-nigeroside and 4-nitrophenyl α-isomaltoside). These hydrolysis and transglucosylation properties of LJAG31 are different from those of mold (Acremonium implicatum) α-1,3-glucosidase of glycoside hydrolase family 31.     

The thermostable alpha-L-rhamnosidase RamA of Clostridium stercorarium: biochemical characterization and primary structure of a bacterial alpha-L-rhamnoside hydrolase, a new type of inverting glycoside hydrolase

An alpha-L-rhamnosidase clone was isolated from a genomic library of the thermophilic anaerobic bacterium Clostridium stercorarium and its primary structure was determined. The recombinant gene product, RamA, was expressed in Escherichia coli, purified to homogeneity and characterized. It is a dimer of two identical subunits with a monomeric molecular mass of 95 kDa in SDS polyacrylamide gel electrophoresis. At pH 7.5 it is optimally active at 60 degrees C and insensitive to moderate concentrations of Triton X100, ethanol and EDTA. It hydrolysed p-nitrophenyl-alpha-L-rhamnopyranoside, naringin and hesperidin with a specific activity of 82, 1.5 and 0.46 U mg-1 respectively. Hydrolysis occurs by inversion of the anomeric configuration as detected using 1H-NMR, indicating a single displacement mechanism. Naringin was hydrolysed to rhamnose and prunin, which could further be degraded by incubation with a thermostable beta-glucosidase. The secondary structure of RamA consists of 27% alpha-helices and 50% beta-sheets, as detected by circular dichroism. The primary structure of the ramA gene has no similarity to other glycoside hydrolase sequences and possibly is the first member of a new enzyme family.     

The hydrolase and transferase activity of an inverting mutant sialidase using non-natural beta-sialoside substrates

The Y370G inverting mutant sialidase from Micromonospora viridifaciens possesses beta-sialidase activity with phenyl beta-sialoside (Ph-betaNeuAc) to give alpha-sialic acid as the first formed product. The derived catalytic rate constants for k(cat) and k(cat)/K(m) are 13.3 +/- 0.3 and (2.9 +/- 0.3) x 10(5) M(-)(1) s(-)(1), respectively. This enzyme is highly specific for the phenyl substrate, with substituted phenyl and thiophenyl leaving groups having k(cat) values that are at least 1000-fold lower. In addition, the Y370G mutant can transfer the sialic acid moiety from Ph-betaNeuAc to lactose in yields of up to 13%. Greater than 90% of the sialyl-lactose product formed in the coupling reactions is the alpha-2,6-isomer. A library encoding 6 x 10(5) different sialidases was constructed by mutating Y370, E260, T309, N310, and N311, residues that include and are proximal the catalytic tyrosine residue. A total of 2628 individuals were screened for hydrolytic activity against 4-nitrophenyl 2-thio-beta-sialoside and 4-methylumbelliferyl beta-sialoside. However, none of the mutants screened possessed a significant activity against either of the beta-sialosides.     

Three-dimensional structure of an intact glycoside hydrolase family 15 glucoamylase from Hypocrea jecorina

The three-dimensional structure of a complete Hypocrea jecorina glucoamylase has been determined at 1.8 A resolution. The presented structure model includes the catalytic and starch binding domains and traces the course of the 37-residue linker segment. While the structures of other fungal and yeast glucoamylase catalytic and starch binding domains have been determined separately, this is the first intact structure that allows visualization of the juxtaposition of the starch binding domain relative to the catalytic domain. The detailed interactions we see between the catalytic and starch binding domains are confirmed in a second independent structure determination of the enzyme in a second crystal form. This second structure model exhibits an identical conformation compared to the first structure model, which suggests that the H. jecorina glucoamylase structure we report is independent of crystal lattice contact restraints and represents the three-dimensional structure found in solution. The proposed starch binding regions for the starch binding domain are aligned with the catalytic domain in the three-dimensional structure in a manner that supports the hypothesis that the starch binding domain serves to target the glucoamylase at sites where the starch granular matrix is disrupted and where the enzyme might most effectively function.     

Identification of difructose dianhydride I synthase/hydrolase from an oral bacterium establishes a novel glycoside hydrolase family

Fructooligosaccharides and their anhydrides are widely used as health-promoting foods and prebiotics. Various enzymes acting on β-D-fructofuranosyl linkages of natural fructan polymers have been used to produce functional compounds. However, enzymes that hydrolyze and form α-D-fructofuranosyl linkages have been less studied. Here, we identified the BBDE_2040 gene product from Bifidobacterium dentium (α-D-fructofuranosidase and difructose dianhydride I synthase/hydrolase from Bifidobacterium dentium [αFFase1]) as an enzyme with α-D-fructofuranosidase and α-D-arabinofuranosidase activities and an anomer-retaining manner. αFFase1 is not homologous with any known enzymes, suggesting that it is a member of a novel glycoside hydrolase family. When caramelized fructose sugar was incubated with αFFase1, conversions of β-D-Frup-(2→1)-α-D-Fruf to α-D-Fruf-1,2′:2,1′-β-D-Frup (diheterolevulosan II) and β-D-Fruf-(2→1)-α-D-Fruf (inulobiose) to α-D-Fruf-1,2′:2,1′-β-D-Fruf (difructose dianhydride I [DFA I]) were observed. The reaction equilibrium between inulobiose and DFA I was biased toward the latter (1:9) to promote the intramolecular dehydrating condensation reaction. Thus, we named this enzyme DFA I synthase/hydrolase. The crystal structures of αFFase1 in complex with β-D-Fruf and β-D-Araf were determined at the resolutions of up to 1.76 Å. Modeling of a DFA I molecule in the active site and mutational analysis also identified critical residues for catalysis and substrate binding. The hexameric structure of αFFase1 revealed the connection of the catalytic pocket to a large internal cavity via a channel. Molecular dynamics analysis implied stable binding of DFA I and inulobiose to the active site with surrounding water molecules. Taken together, these results establish DFA I synthase/hydrolase as a member of a new glycoside hydrolase family (GH172).     

The first structure of a glycoside hydrolase family 61 member, Cel61B from Hypocrea jecorina, at 1.6 A resolution

The glycoside hydrolase (GH) family 61 is a long-recognized, but still recondite, class of proteins, with little known about the activity, mechanism or function of its more than 70 members. The best-studied GH family 61 member, Cel61A of the filamentous fungus Hypocrea jecorina, is known to be an endoglucanase, but it is not clear if this represents the main activity or function of this family in vivo. We present here the first structure for this family, that of Cel61B from H. jecorina. The best-quality crystals were formed in the presence of nickel, and the crystal structure was solved to 1.6 Å resolution using a single-wavelength anomalous dispersion method with nickel as the source of anomalous scatter. Cel61B lacks a carbohydrate-binding module and is a single-domain protein that folds into a twisted β-sandwich. A structure-aided sequence alignment of all GH family 61 proteins identified a highly conserved group of residues on the surface of Cel61B. Within this patch of mostly polar amino acids was a site occupied by the intramolecular nickel hexacoordinately bound in the solved structure. In the Cel61B structure, there is no easily identifiable carbohydrate-binding cleft or pocket or catalytic center of the types normally seen in GHs. A structural comparison search showed that the known structure most similar to Cel61B is that of CBP21 from the Gram-negative soil bacterium Serratia marcescens, a member of the carbohydrate-binding module family 33 proteins. A polar surface patch highly conserved in that structural family has been identified in CBP21 and shown to be involved in chitin binding and in the protein's enhancement of chitinase activities. The analysis of the Cel61B structure is discussed in light of our continuing research to better understand the activities and function of GH family 61.     

Identification of Mur, an atypical peptidoglycan hydrolase derived from Leuconostoc citreum

A gene encoding a protein homologous to known bacterial N-acetyl-muramidases has been cloned from Leuconostoc citreum by a PCR-based approach. The encoded protein, Mur, consists of 209 amino acid residues with a calculated molecular mass of 23,821 Da including a 31-amino-acid putative signal peptide. In contrast to most of the other known peptidoglycan hydrolases, L. citreum Mur protein does not contain amino acid repeats involved in cell wall binding. The purified L. citreum Mur protein was shown to exhibit peptidoglycan-hydrolyzing activity by renaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. An active chimeric protein was constructed by fusion of L. citreum Mur to the C-terminal repeat-containing domain (cA) of AcmA, the major autolysin of Lactococcus lactis. Expression of the Mur-cA fusion protein was able to complement an acmA mutation in L. lactis; normal cell separation after cell division was restored by Mur-cA expression.     

Molecular cloning and characterization of Bifidobacterium bifidum 1,2-alpha-L-fucosidase (AfcA), a novel inverting glycosidase (glycoside hydrolase family 95)

A genomic library of Bifidobacterium bifidum constructed in Escherichia coli was screened for the ability to hydrolyze the alpha-(1-->2) linkage of 2'-fucosyllactose, and a gene encoding 1,2-alpha-l-fucosidase (AfcA) was isolated. The afcA gene was found to comprise 1,959 amino acid residues with a predicted molecular mass of 205 kDa and containing a signal peptide and a membrane anchor at the N and C termini, respectively. A domain responsible for fucosidase activity (the Fuc domain; amino acid residues 577 to 1474) was localized by deletion analysis and then purified as a hexahistidine-tagged protein. The recombinant Fuc domain specifically hydrolyzed the terminal alpha-(1-->2)-fucosidic linkages of various oligosaccharides and a sugar chain of a glycoprotein. The stereochemical course of the hydrolysis of 2'-fucosyllactose was determined to be inversion by using (1)H nuclear magnetic resonance. The primary structure of the Fuc domain exhibited no similarity to those of any glycoside hydrolases (GHs) but showed high similarity to those of several hypothetical proteins in a database. Thus, it was revealed that the AfcA protein constitutes a novel inverting GH family (GH family 95).     

The unique glycoside hydrolase family 77 amylomaltase from Borrelia burgdorferi with only catalytic triad conserved

Glycoside hydrolase family 77 (GH77) contains prokaryotic amylomaltases and plant-disproportionating enzymes (both possessing the 4-alpha-glucanotransferase activity; EC 2.4.1.25). Together with GH13 and GH70, it forms the clan GH-H, known as the alpha-amylase family. Bioinformatics analysis revealed that the putative GH77 amylomaltase (MalQ) from the Lyme disease spirochaete Borrelia burgdorferi genome (BB0166) contains several amino acid substitutions in the positions that are important and conserved in all GH77 amylomaltases. The most important mutation concerned the functionally important arginine positioned two residues before the catalytic nucleophile that is replaced by lysine in B. burgdorferi MalQ. Similar remarkable substitutions were found in two other putative GH77 amylomaltases from related borreliae. In order to confirm the exclusive sequence features and to verify the eventual enzymatic activity, the malQ gene from B. burgdorferi was amplified using PCR. A c. 1.5-kb amplified DNA fragment was sequenced, cloned and expressed in Escherichia coli, and the resulting recombinant protein was preliminarily characterized for its activity towards glucose (G1) and a series of malto-oligosaccharides (G2-G7). This study confirmed that the remarkable substitution of the arginine really exists and the GH77 MalQ protein from B. burgdorferi is a functional amylomaltase because it is able to hydrolyse the malto-oligosaccharides as well as to form their longer transglycosylation products.     

里氏木霉GH61家族糖苷酶的高效表达及酶学特性研究

【目的】GH61家族糖苷水解酶具有葡聚糖氧化酶活性,通过对葡聚糖链的随机氧化而破坏木质纤维素的结晶结构,从而使木质纤维素容易被纤维素酶降解。重组表达、纯化获得里氏木霉的GH61家族糖苷水解酶(TrGH61,原名为EGⅣ),并研究其在纤维素酶水解木质纤维素中的作用。【方法】通过Overlap PCR将里氏木霉丙酮酸脱羧酶的启动子、纤维二糖水解酶cbh1的信号肽、EGⅣ基因和PDC终止子依次连接构建了里氏木霉的表达盒,通过该表达盒使TrGH61蛋白基因整合到里氏木霉的基因组DNA上进行同源表达。研究表达产物TrGH61的水解活性、与纤维素酶水解协同效应,以及TrGH61作为金属氧化酶的特性研究。【结果】在PDC启动子的作用下,TrGH61得到高效表达,摇瓶培养的表达量达到2.33 g/L。TrGH61有微弱的内切葡萄糖苷酶活性,比活力为0.02 IU/mg,但能显著提高纤维素酶水解稻草粉的活性,协同度最高可达1.998。低浓度的金属离子Cu2+、Co2+和还原性电子供体还原型谷胱甘肽、L-抗坏血酸、焦性没食子酸均能显著促进其水解效应。TrGH61能够降低稻草粉纤维素聚合度和结晶度。【结论】通过PDC启动子可以实现TrGH61蛋白高效组成型表达,TrGH61作为纤维素酶活性促进因子,通过破坏纤维素结晶结构作用机制协同增强纤维素酶水解木质纤维素。     

New perspective on glycoside hydrolase binding to lignin from pretreated corn stover

Background

Non-specific binding of cellulases to lignin has been implicated as a major factor in the loss of cellulase activity during biomass conversion to sugars. It is believed that this binding may strongly impact process economics through loss of enzyme activities during hydrolysis and enzyme recycling scenarios. The current model suggests glycoside hydrolase activities are lost though non-specific/non-productive binding of carbohydrate-binding domains to lignin, limiting catalytic site access to the carbohydrate components of the cell wall.

Results

In this study, we have compared component enzyme affinities of a commercial Trichoderma reesei cellulase formulation, Cellic CTec2, towards extracted corn stover lignin using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and p-nitrophenyl substrate activities to monitor component binding, activity loss, and total protein binding. Protein binding was strongly affected by pH and ionic strength. β-d-glucosidases and xylanases, which do not have carbohydrate-binding modules (CBMs) and are basic proteins, demonstrated the strongest binding at low ionic strength, suggesting that CBMs are not the dominant factor in enzyme adsorption to lignin. Despite strong adsorption to insoluble lignin, β-d-glucosidase and xylanase activities remained high, with process yields decreasing only 4–15 % depending on lignin concentration.

Conclusion

We propose that specific enzyme adsorption to lignin from a mixture of biomass-hydrolyzing enzymes is a competitive affinity where β-d-glucosidases and xylanases can displace CBM interactions with lignin. Process parameters, such as temperature, pH, and salt concentration influence the individual enzymes’ affinity for lignin, and both hydrophobic and electrostatic interactions are responsible for this binding phenomenon. Moreover, our results suggest that concern regarding loss of critical cell wall degrading enzymes to lignin adsorption may be unwarranted when complex enzyme mixtures are used to digest biomass.

     

Structure and activity of Paenibacillus polymyxa xyloglucanase from glycoside hydrolase family 44

The enzymatic degradation of plant polysaccharides is emerging as one of the key environmental goals of the early 21st century, impacting on many processes in the textile and detergent industries as well as biomass conversion to biofuels. One of the well known problems with the use of nonstarch (nonfood)-based substrates such as the plant cell wall is that the cellulose fibers are embedded in a network of diverse polysaccharides, including xyloglucan, that renders access difficult. There is therefore increasing interest in the "accessory enzymes," including xyloglucanases, that may aid biomass degradation through removal of "hemicellulose" polysaccharides. Here, we report the biochemical characterization of the endo-β-1,4-(xylo)glucan hydrolase from Paenibacillus polymyxa with polymeric, oligomeric, and defined chromogenic aryl-oligosaccharide substrates. The enzyme displays an unusual specificity on defined xyloglucan oligosaccharides, cleaving the XXXG-XXXG repeat into XXX and GXXXG. Kinetic analysis on defined oligosaccharides and on aryl-glycosides suggests that both the -4 and +1 subsites show discrimination against xylose-appended glucosides. The three-dimensional structures of PpXG44 have been solved both in apo-form and as a series of ligand complexes that map the -3 to -1 and +1 to +5 subsites of the extended ligand binding cleft. Complex structures are consistent with partial intolerance of xylosides in the -4' subsites. The atypical specificity of PpXG44 may thus find use in industrial processes involving xyloglucan degradation, such as biomass conversion, or in the emerging exciting applications of defined xyloglucans in food, pharmaceuticals, and cellulose fiber modification.     

Biochemical characterization of a glycoside hydrolase family 61 endoglucanase from Aspergillus kawachii

The glycoside hydrolase family 61 endoglucanase from Aspergillus kawachii (AkCel61) is a modular enzyme that consists of a catalytic domain and a carbohydrate-binding module belonging to family 1 (CBM1) that are connected by a Ser-Thr linker region longer than 100 amino acids. We expressed the recombinant AkCel61, wild-type enzyme (rAkCel61), and a truncated enzyme consisting of the catalytic domain (rAkCel61ΔCBM) in Pichia pastoris and analyzed their biochemical properties. Purified rAkCel61 and rAkCel61ΔCBM migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and were demonstrated to have apparent molecular masses of 81,000 and 34,000 Da, respectively. After treatment with endoglycosidase H, both proteins showed an increase in mobility, thus, demonstrating estimated molecular masses of 78,000 and 28,000 Da, respectively. Mass spectrometry analysis revealed that rAkCel61 and rAkCel61ΔCBM expressed in P. pastoris are heterogeneous due to protein glycosylation. The rAkCel61 protein bound to crystalline cellulose but not to arabinoxylan. The rAkCel61 and rAkCel61ΔCBM proteins produced small amounts of oligosaccharides from soluble carboxymethylcellulose. They also exhibited a slight hydrolytic activity toward laminarin. However, they showed no detectable activity toward microcrystalline cellulose, arabinoxylan, and pectin. Both recombinant enzymes also showed no detectable activity toward p-nitrophenyl β-d-glucoside, p-nitrophenyl β-d-cellobioside, and p-nitrophenyl β-d-cellotrioside. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Sequence fingerprints of enzyme specificities from the glycoside hydrolase family GH57

The glycoside hydrolase family 57 (GH57) contains five well-established enzyme specificities: α-amylase, amylopullulanase, branching enzyme, 4-α-glucanotransferase and α-galactosidase. Around 700 GH57 members originate from Bacteria and Archaea, a substantial number being produced by thermophiles. An intriguing feature of family GH57 is that only slightly more than 2 % of its members (i.e., less than 20 enzymes) have already been biochemically characterized. The main goal of the present bioinformatics study was to retrieve from databases, and analyze in detail, sequences having clear features of the five GH57 enzyme specificities mentioned above. Of the 367 GH57 sequences, 56 were evaluated as α-amylases, 99 as amylopullulanases, 158 as branching enzymes, 46 as 4-α-glucanotransferases and 8 as α-galactosidases. Based on the analysis of collected sequences, sequence logos were created for each specificity and unique sequence features were identified within the logos. These features were proposed to define the so-called sequence fingerprints of GH57 enzyme specificities. Domain arrangements characteristic of the individual enzyme specificities as well as evolutionary relationships within the family GH57 are also discussed. The results of this study could find use in rational protein design of family GH57 amylolytic enzymes and also in the possibility of assigning a GH57 specificity to a hypothetical GH57 member prior to its biochemical characterization.     

Computational analysis of glycoside hydrolase family 1 specificities

Glycoside hydrolase family 1 consists of beta-glucosidases, beta-galactosidases, 6-phospho-beta-galactosidases, myrosinases, and other enzymes having similar primary and tertiary structures but diverse specificities. Among these enzymes, beta-glucosidases hydrolyze cellobiose to glucose, and therefore they are key players in any cellulose to glucose process. All family members attack beta-glycosidic bonds between a pyranosyl glycon and an aglycon, but most have little specificity for the aglycon or for the bond configuration. Furthermore, glycon specificity is not absolute. Sixteen family members (six beta-glucosidases, two cyanogenic beta-glucosidases, one 6-phospho-beta-galactosidase, two myrosinases, and five beta-glycosidases) have known tertiary structures. We have used automated docking to computationally bind disaccharides with allopyranosyl, galactopyranosyl, glucopyranosyl, mannopyranosyl, 6-phosphogalactopyranosyl, and 6-phosphoglucopyranosyl glycons, all linked by beta-(1,2), beta-(1,3), beta-(1,4), and beta-(1,6)-glycosidic bonds to beta-glucopyranoside aglycons, along with beta-(1,1-thio)-allopyranosyl, -galactopyranosyl, -glucopyranosyl, and -mannopyranosyl) beta-glucopyranosides, into all of these structures to investigate the structural determinants of their enzyme specificities. The following are the eight active-site residues: Glu191, Thr194, Phe205, Asn285, Arg336, Asn376, Trp378, and Trp465 (Zea mays beta-glucosidase numbering), that control a significant amount of glycon specificity. (c) 2008 Wiley Periodicals, Inc. Biopolymers 89: 1021-1031, 2008.This article was originally published online as an accepted preprint. The "Published Online" date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com.