Crystal structure of truncated Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase in complex with beta-1,3-1,4-cellotriose

Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase (Fsbeta-glucanase) catalyzes the specific hydrolysis of beta-1,4 glycosidic bonds adjacent to beta-1,3 linkages in beta-D-glucans or lichenan. This is the first report to elucidate the crystal structure of a truncated Fsbeta-glucanase (TFsbeta-glucanase) in complex with beta-1,3-1,4-cellotriose, a major product of the enzyme reaction. The crystal structures, at a resolution of 2.3 angstroms, reveal that the overall fold of TFsbeta-glucanase remains virtually unchanged upon sugar binding. The enzyme accommodates five glucose residues, forming a concave active cleft. The beta-1,3-1,4-cellotriose with subsites -3 to -1 bound to the active cleft of TFsbeta-glucanase with its reducing end subsite -1 close to the key catalytic residues Glu56 and Glu60. All three subsites of the beta-1,3-1,4-cellotriose adopted a relaxed C(1)4 conformation, with a beta-1,3 glycosidic linkage between subsites -2 and -1, and a beta-1,4 glycosidic linkage between subsites -3 and -2. On the basis of the enzyme-product complex structure observed in this study, a catalytic mechanism and substrate binding conformation of the active site of TFsbeta-glucanase is proposed.     

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.     

The kappa-carrageenase of the marine bacterium Cytophaga drobachiensis. Structural and phylogenetic relationships within family-16 glycoside hydrolases

We report here cloning from the marine gliding bacterium Cytophaga drobachiensis of kappa-carrageenase, a glycoside hydrolase involved in the degradation of kappa-carrageenan. Structural features in the nucleotide sequence are pointed out, including the presence of an octameric omega sequence similar to the ribosome-binding sites of various eukaryotes and prokaryotes. The cgkA gene codes for a protein of 545 aa, with a signal peptide of 35 aa and a 229-aa-long posttranslationaly processed C-terminal domain. The enzyme displays the overall folding and catalytic domain characteristics of family 16 of glycoside hydrolases, which comprises other beta-1,4-alpha-1,3-D/L- galactan hydrolases, beta-1,3-D-glucan hydrolases (laminarinases), beta- 1,4-1,3-D-glucan hydrolases (lichenases), and beta-1,4-D-xyloglucan endotransglycosylases. In order to address the origin and evolution of CgkA, a comprehensive phylogenetic tree of family 16 was built using parsimony analysis. Family-16 glycoside hydrolases cluster according to their substrate specificity, regardless of their phylogenetic distribution over eubacteria and eukaryotes. Such a topology suggests that the general homology between laminarinases, agarases, kappa- carrageenases, lichenases, and xyloglucan endotransglycosylases has arisen through gene duplication, likely from an ancestral protein with laminarinase activity.      

A truncated Fibrobacter succinogenes 1,3-1,4-beta-d-glucanase with improved enzymatic activity and thermotolerance

As an approach to improving Fibrobacter succinogenes 1,3-1,4-beta-d-glucanase (Fsbeta-glucanase) for use in industry and to studying the structure-function relationship of the C-terminus in the enzyme, a C-terminally truncated ( approximately 10 kDa) Fsbeta-glucanase was generated using a PCR-based gene truncation method and then overexpressed in either Escherichia coli BL21(DE3) or Pichia pastoris strain X-33 host cells. The initial rate kinetics, protein folding, and thermostability of the wild-type and truncated glucanases were characterized. The truncated enzyme expressed in Pichia cells was found to be glycosylated and composed of two dominant polypeptide bands as judged by SDS-PAGE. An approximate 3-4-fold increase in the turnover rate (k(cat)), relative to that of the full-length enzyme, was detected for the purified truncated glucanases produced in E. coli (designated TF-glucanase) or Pichia host cells (designated glycosylated TF-glucanase). The glycosylated TF-glucanase is the most active known 1,3-1,4-beta-d-glucanase, with a specific activity of 10 800 +/- 200 units/mg. Similar binding affinities for lichenan (K(m) = 2.5-2.89 mg/mL) were detected for the full-length enzyme, TF-glucanase, and glycosylated TF-glucanase. Both forms of truncated glucanase retained more than 80% of their original enzymatic activity after a 10 min incubation at 90 degrees C, whereas the full-length enzyme possessed only 30% of its original enzymatic activity after the same treatment. This report demonstrates that deletion of the C-terminal region ( approximately 10 kDa) in Fsbeta-glucanase, consisting of serine-rich repeats and a basic terminal domain rich in positively charged amino acids, significantly increases the catalytic efficiency and thermotolerance of the enzyme.     

Novel carbohydrate-binding module of beta-1,3-xylanase from a marine bacterium, Alcaligenes sp. strain XY-234

A beta-1,3-xylanase gene (txyA) from a marine bacterium, Alcaligenes sp. strain XY-234, has been cloned and sequenced. txyA consists of a 1,410-bp open reading frame that encodes 469 amino acid residues with a calculated molecular mass of 52,256 Da. The domain structure of the beta-1,3-xylanase (TxyA) consists of a signal peptide of 22 amino acid residues, followed by a catalytic domain which belongs to family 26 of the glycosyl hydrolases, a linker region with one array of DGG and six repeats of DNGG, and a novel carbohydrate-binding module (CBM) at the C terminus. The recombinant TxyA hydrolyzed beta-1,3-xylan but not other polysaccharides such as beta-1,4-xylan, carboxymethylcellulose, curdlan, glucomannan, or beta-1,4-mannan. TxyA was capable of binding specifically to beta-1,3-xylan. The analysis using truncated TxyA lacking either the N- or C-terminal region indicated that the region encoding the CBM was located between residues 376 and 469. Binding studies on the CBM revealed that the K(d) and the maximum amount of protein bound to beta-1,3-xylan were 4.2 microM and 18.2 micromol/g of beta-1,3-xylan, respectively. Furthermore, comparison of the enzymatic properties between proteins with and without the CBM strongly indicated that the CBM of TxyA plays an important role in the hydrolysis of beta-1,3-xylan.     

Molecular characterization and expression in Escherichia coli of three beta-1,3-glucanase genes from Lysobacter enzymogenes strain N4-7

Lysobacter enzymogenes strain N4-7 produces multiple biochemically distinct extracellular beta-1,3-glucanase activities. The gluA, gluB, and gluC genes, encoding enzymes with beta-1,3-glucanase activity, were identified by a reverse-genetics approach following internal amino acid sequence determination of beta-1,3-glucanase-active proteins partially purified from culture filtrates of strain N4-7. Analysis of gluA and gluC gene products indicates that they are members of family 16 glycoside hydrolases that have significant sequence identity to each other throughout the catalytic domain but that differ structurally by the presence of a family 6 carbohydrate-binding domain within the gluC product. Analysis of the gluB gene product indicates that it is a member of family 64 glycoside hydrolases. Expression of each gene in Escherichia coli resulted in the production of proteins with beta-1,3-glucanase activity. Biochemical analyses of the recombinant enzymes indicate that GluA and GluC exhibit maximal activity at pH 4.5 and 45 degrees C and that GluB is most active between pH 4.5 and 5.0 at 41 degrees C. Activity of recombinant proteins against various beta-1,3 glucan substrates indicates that GluA and GluC are most active against linear beta-1,3 glucans, while GluB is most active against the insoluble beta-1,3 glucan substrate zymosan A. These data suggest that the contribution of beta-1,3-glucanases to the biocontrol activity of L. enzymogenes may be due to complementary activities of these enzymes in the hydrolysis of beta-1,3 glucans from fungal cell walls.     

Molecular modeling of family GH16 glycoside hydrolases: potential roles for xyloglucan transglucosylases/hydrolases in cell wall modification in the poaceae

Family GH16 glycoside hydrolases can be assigned to five subgroups according to their substrate specificities, including xyloglucan transglucosylases/hydrolases (XTHs), (1,3)-beta-galactanases, (1,4)-beta-galactanases/kappa-carrageenases, "nonspecific" (1,3/1,3;1,4)-beta-D-glucan endohydrolases, and (1,3;1,4)-beta-D-glucan endohydrolases. A structured family GH16 glycoside hydrolase database has been constructed (http://www.ghdb.uni-stuttgart.de) and provides multiple sequence alignments with functionally annotated amino acid residues and phylogenetic trees. The database has been used for homology modeling of seven glycoside hydrolases from the GH16 family with various substrate specificities, based on structural coordinates for (1,3;1,4)-beta-D-glucan endohydrolases and a kappa-carrageenase. In combination with multiple sequence alignments, the models predict the three-dimensional (3D) dispositions of amino acid residues in the substrate-binding and catalytic sites of XTHs and (1,3/1,3;1,4)-beta-d-glucan endohydrolases; there is no structural information available in the databases for the latter group of enzymes. Models of the XTHs, compared with the recently determined structure of a Populus tremulos x tremuloides XTH, reveal similarities with the active sites of family GH11 (1,4)-beta-D-xylan endohydrolases. From a biological viewpoint, the classification, molecular modeling and a new 3D structure of the P. tremulos x tremuloides XTH establish structural and evolutionary connections between XTHs, (1,3;1,4)-beta-D-glucan endohydrolases and xylan endohydrolases. These findings raise the possibility that XTHs from higher plants could be active not only on cell wall xyloglucans, but also on (1,3;1,4)-beta-D-glucans and arabinoxylans, which are major components of walls in grasses. A role for XTHs in (1,3;1,4)-beta-D-glucan and arabinoxylan modification would be consistent with the apparent overrepresentation of XTH sequences in cereal expressed sequence tags databases.     

The family 11 carbohydrate-binding module of Clostridium thermocellum Lic26A-Cel5E accommodates beta-1,4- and beta-1,3-1,4-mixed linked glucans at a single binding site

Modular glycoside hydrolases that attack recalcitrant polymers generally contain noncatalytic carbohydrate-binding modules (CBMs), which play a critical role in the action of these enzymes by localizing the appended catalytic domains onto the surface of insoluble polysaccharide substrates. Type B CBMs, which recognize single polysaccharide chains, display ligand specificities that are consistent with the substrates hydrolyzed by the associated catalytic domains. In enzymes that contain multiple catalytic domains with distinct substrate specificities, it is unclear how these different activities influence the evolution of the ligand recognition profile of the appended CBM. To address this issue, we have characterized the properties of a family 11 CBM (CtCBM11) in Clostridium thermocellum Lic26A-Cel5E, an enzyme that contains GH5 and GH26 catalytic domains that display beta-1,4- and beta-1,3-1,4-mixed linked endoglucanase activity, respectively. Here we show that CtCBM11 binds to both beta-1,4- and beta-1,3-1,4-mixed linked glucans, displaying K(a) values of 1.9 x 10(5), 4.4 x 10(4), and 2 x 10(3) m(-1) for Glc-beta1,4-Glc-beta1,4-Glc-beta1,3-Glc, Glc-beta1,4-Glc-beta1,4-Glc-beta1,4-Glc, and Glc-beta1,3-Glc-beta1,4-Glc-beta1,3-Glc, respectively, demonstrating that CBMs can display a preference for mixed linked glucans. To determine whether these ligands are accommodated in the same or diverse sites in CtCBM11, the crystal structure of the protein was solved to a resolution of 1.98 A. The protein displays a beta-sandwich with a concave side that forms a potential binding cleft. Site-directed mutagenesis revealed that Tyr(22), Tyr(53), and Tyr(129), located in the putative binding cleft, play a central role in the recognition of all the ligands recognized by the protein. We propose, therefore, that CtCBM11 contains a single ligand-binding site that displays affinity for both beta-1,4- and beta-1,3-1,4-mixed linked glucans.     

Transgenic Tobacco plants expressing bacterial genes encoded the thermostable glucanases

It is shown that bacterial genes for thermostable beta-glucanases are expressed retaining their activity and substrate specificity. The leader peptide of the carrot extensin exerts effective secretion of the bacterial enzymes into the intercellular space of the plant tissue. Expression of the bacterial gene for beta-1,3-glucanase in plant tissues alters their morphogenetic potential. Regeneration of shoots from the calli of these plant lines requires a six- to eightfold increase in cytokinin (6-BAP) concentration in comparison with the control lines and the transgenic lines expressing beta-1,3-1,4-glucanase. Rooting of transgenic plants expressing the bacterial gene for beta-1,3-glucanase occurs much faster. The transgenic plants obtained in the study are proposed as model objects for investigating the role of glucanases in plants.     

Cold-active winter rye glucanases with ice-binding capacity

Extracellular pathogenesis-related proteins, including glucanases, are expressed at cold temperatures in winter rye (Secale cereale) and display antifreeze activity. We have characterized recombinant cold-induced glucanases from winter rye to further examine their roles and contributions to cold tolerance. Both basic beta-1,3-glucanases and an acidic beta-1,3;1,4-glucanase were expressed in Escherichia coli, purified, and assayed for their hydrolytic and antifreeze activities in vitro. All were found to be cold active and to retain partial hydrolytic activity at subzero temperatures (e.g. 14%-35% at -4 degrees C). The two types of glucanases had antifreeze activity as measured by their ability to modify the growth of ice crystals. Structural models for the winter rye beta-1,3-glucanases were developed on which putative ice-binding surfaces (IBSs) were identified. Residues on the putative IBSs were charge conserved for each of the expressed glucanases, with the exception of one beta-1,3-glucanase recovered from nonacclimated winter rye in which a charged amino acid was present on the putative IBS. This protein also had a reduced antifreeze activity relative to the other expressed glucanases. These results support the hypothesis that winter rye glucanases have evolved to inhibit the formation of large, potentially fatal ice crystals, in addition to having enzymatic activity with a potential role in resisting infection by psychrophilic pathogens. Glucanases of winter rye provide an interesting example of protein evolution and adaptation aimed to combat cold and freezing conditions.     

Structural analysis of CPF_2247, a novel α-amylase from Clostridium perfringens

CPF_2247 from Clostridium perfringens ATCC 13124 was identified as a putative carbohydrate‐active enzyme by its low sequence identity to endo‐β‐1,4‐glucanases belonging to family 8 of the glycoside hydrolase classification. The X‐ray crystal structure of CPF_2247 determined to 2.0 Å resolution by single‐wavelength anomalous dispersion using seleno‐methionine‐substituted protein revealed an (α/α)₆ barrel fold. A large cleft on the surface of the protein contains residues that are structurally conserved with key elements of the catalytic machinery in clan GH‐M glycoside hydrolases. Assessment of CPF_2247 as a carbohydrate‐active enzyme disclosed α‐glucanase activity on amylose, glycogen, and malto‐oligosaccharides. Proteins 2011;. © 2011 Wiley‐Liss, Inc.     

Innate immunity in a pyralid moth: functional evaluation of domains from a beta-1,3-glucan recognition protein

Invertebrates, like vertebrates, utilize pattern recognition proteins for detection of microbes and subsequent activation of innate immune responses. We report structural and functional properties of two domains from a beta-1,3-glucan recognition protein present in the hemolymph of a pyralid moth, Plodia interpunctella. A recombinant protein corresponding to the first 181 amino-terminal residues bound to beta-1,3-glucan, lipopolysaccharide, and lipoteichoic acid, polysaccharides found on cell surfaces of microorganisms, and also activated the prophenoloxidase-activating system, an immune response pathway in insects. The amino-terminal domain consists primarily of an alpha-helical secondary structure with a minor beta-structure. This domain was thermally stable and resisted proteolytic degradation. The 290 residue carboxyl-terminal domain, which is similar in sequence to glucanases, had less affinity for the polysaccharides, did not activate the prophenoloxidase cascade, had a more complicated CD spectrum, and was heat-labile and susceptible to proteinase digestion. The carboxyl-terminal domain bound to laminarin, a beta-1,3-glucan with beta-1,6 branches, but not to curdlan, a beta-1,3-glucan that lacks branching. These results indicate that the two domains of Plodia beta-1,3-glucan recognition protein, separated by a putative linker region, bind microbial polysaccharides with differing specificities and that the amino-terminal domain, which is unique to this class of pattern recognition receptors from invertebrates, is responsible for stimulating prophenoloxidase activation.     

The crystal structure of the family 6 carbohydrate binding module from Cellvibrio mixtus endoglucanase 5a in complex with oligosaccharides reveals two distinct binding sites with different ligand specificities

Glycoside hydrolases that release fixed carbon from the plant cell wall are of considerable biological and industrial importance. These hydrolases contain non-catalytic carbohydrate binding modules (CBMs) that, by bringing the appended catalytic domain into intimate association with its insoluble substrate, greatly potentiate catalysis. Family 6 CBMs (CBM6) are highly unusual because they contain two distinct clefts (cleft A and cleft B) that potentially can function as binding sites. Henshaw et al. (Henshaw, J., Bolam, D. N., Pires, V. M. R., Czjzek, M., Henrissat, B., Ferreira, L. M. A., Fontes, C. M. G. A., and Gilbert, H. J. (2003) J. Biol. Chem. 279, 21552-21559) show that CmCBM6 contains two binding sites that display both similarities and differences in their ligand specificity. Here we report the crystal structure of CmCBM6 in complex with a variety of ligands that reveals the structural basis for the ligand specificity displayed by this protein. In cleft A the two faces of the terminal sugars of beta-linked oligosaccharides stack against Trp-92 and Tyr-33, whereas the rest of the binding cleft is blocked by Glu-20 and Thr-23, residues that are not present in CBM6 proteins that bind to the internal regions of polysaccharides in cleft A. Cleft B is solvent-exposed and, therefore, able to bind ligands because the loop, which occludes this region in other CBM6 proteins, is much shorter and flexible (lacks a conserved proline) in CmCBM6. Subsites 2 and 3 of cleft B accommodate cellobiose (Glc-beta-1,4-Glc), subsite 4 will bind only to a beta-1,3-linked glucose, whereas subsite 1 can interact with either a beta-1,3- or beta-1,4-linked glucose. These different specificities of the subsites explain how cleft B can accommodate beta-1,4-beta-1,3- or beta-1,3-beta-1,4-linked gluco-configured ligands.     

Differences in active site structure in a family of beta-glucan endohydrolases deduced from the kinetics of inactivation by epoxyalkyl beta-oligoglucosides

The active sites of a spectrum of beta-glucan endohydrolases with distinct, but related substrate specificities have been probed using a series of epoxyalkyl beta-glycosides of glucose, cellobiose, cellotriose, laminaribiose, laminaritriose, 3O-beta-D-glucosyl-cellobiose and 4O-beta-D-glucosyl-laminaribiose with different aglycon chain lengths. The inactivation of each of the endohydrolases by these compounds results from active site-directed inhibitor action, as indicated by the dependence of the inactivation rate on pH, glycosyl chain length and linkage position, aglycon length, and the protective effect of disaccharides derived from the natural substrates. Comparisons of inhibitor specificity between a Bacillus subtilis 1,3;1,4-beta-D-glucan 4-glucanohydrolase (EC 3.2.1.73), a Streptomyces cellulase (EC 3.2.1.4), a Schizophyllum commune cellulase (EC 3.2.1.4), a Rhizopus arrhizus 1,3-(1,3;1,4)-beta-D-glucan 3(4)-glucanohydrolase (EC 3.2.1.6), and a Nicotiana glutinosa 1,3-beta-D-glucan 3-glucanohydrolase (EC 3.2.1.39) demonstrated different tolerances for glycosyl linkage positions in the inactivation process and a critical role of aglycon length reflecting differences in the active site geometry of the enzymes. For the B. subtilis endohydrolase it was concluded that the aglycon residue of the inhibitor spans the glycosyl binding subsite occupied by the 3-substituted glucosyl residue involved in the glucosidic linkage cleaved in the natural substrate. Appropriate positioning of the inhibitor epoxide group with respect to the catalytic amino acids in the active site is crucial to the inactivation step and the number of glucosyl residues in the inhibitor affects aglycon chain length specificity. The importance of this effect differs between the glucanases tested and may be related to the number of glycosyl binding subsites in the active site.     

Molecular cloning, purification and characterization of thermostable beta-1,3-1,4 glucanase from Bacillus subtilis A8-8

A gene encoding a beta-1,3-1,4-glucanase (CelA) belonging to family 5 of glycoside hydrolases was cloned and sequenced from the Bacillus subtilis A8-8. The open-reading-frame of celA comprised 1499 base pairs and the enzyme was composed of 500 amino acids with a molecular mass of 55 kDa. The recombinant beta-1,3-1,4 glucanase was purified by GST-fusion purification system. The pH and temperature optima of the enzyme were 8.0 and 60 degrees C, respectively. The enzyme was stable within pH 6.0-9.0. It was stable up to 60 degrees C and retained 30% of its original activity at 70 degrees C for 60 min. It hydrolyzed lichenan, CMC, xylan, laminarin, avicel and pNPC, but was inactive towards cellobiose. The enzyme activity was markedly activated by Co2+ and Mn2+, but was strongly inactivated by Fe3+. The truncated gene, devoid of cellulose-binding domain (CBD) showed 60% of activity and bound to avicel.     

Purification, characterization, and gene analysis of cellulase (Cel8A) from Lysobacter sp. IB-9374

An enzyme that has both beta-1,4-glucanase and chitosanase activities was found in the culture medium of the soil bacterium Lysobacter sp. IB-9374, a high lysyl endopeptidase-producing strain. The enzyme was purified to homogeneity from the culture filtrate using five purification steps and designated Cel8A. The purified Cel8A had a molecular mass of 41 kDa, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A pH optimum of 5.0 was found for the beta-1,4-glucanase activity, and pH optima of 5.0 and 7.0 were found for the chitosanase activity. Nucleotide sequencing of the Cel8A gene yielded a deduced amino acid sequence that comprises a 33-amino acid, N-terminal signal peptide and a mature enzyme consisting of a 381-residue polypeptide with a predicted molecular mass of 41,241 Da. The amino acid sequence of the Cel8A, which contains the catalytic module of glycosyl hydrolase family 8, is homologous to beta-1,3-1,4-D-glucanase from Bacillus circulans WL-12 and endoglucanase N-257 from B. circulans KSM-N257.     

Function of the family-9 and family-22 carbohydrate-binding modules in a modular beta-1,3-1,4-glucanase/xylanase derived from Clostridium stercorarium Xyn10B

Clostridium stercorarium Xyn10B having hydrolytic activities on xylan and beta-1,3-1,4-glucan is a modular enzyme composed of two family-22 carbohydrate-binding modules (CBMs), a family-10 catalytic module of the glycoside hydrolases, a family-9 CBM, and two S-layer homologous modules, consecutively from the N-terminus. We investigated the function of family-9 and family-22 CBMs in a modular enzyme by comparing the enzymatic properties of a truncated enzyme composed of two family-22 CBMs and the catalytic module (rCBM22-CM), an enzyme composed of the catalytic module and family-9 CBM (rCM-CBM9), an enzyme composed of two family-22 CBMs, the catalytic module, and family-9 CBM (rCBM22-CM-CBM9), and the catalytic module polypeptide (rCM). Although the addition of family-9 CBM to rCM and rCBM22-CM did not significantly change catalytic activity toward xylan and beta-1,3-1,4-glucan, the addition of family-22 CBM to rCM and rCM-CBM9 drastically enhanced catalytic activity toward xylan and especially beta-1,3-1,4-glucan. Furthermore, the addition of family-22 CBM to rCM and rCM-CBM9 shifted the optimum temperature from 65 degrees C to 75 degrees C, but that of family-9 CBM to rCM and rCBM22-CM did not affect the optimum temperature. These facts suggest that the enzyme properties of Xyn10B were mainly dependent on the presence of the family-22 CBMs but not family-9 CBM.     

Identification of glutamic acid 105 at the active site of Bacillus amyloliquefaciens 1,3-1,4-beta-D-glucan 4-glucanohydrolase using epoxide-based inhibitors.

Bacillus amyloliquefaciens 1,3-1,4-beta-D-glucan 4-glucanohydrolase (EC 3.2.1.73) was modified by the mechanism-based, affinity-labeling reagent [14C](3,4)-epoxybutyl beta-D-cellobioside. Following partial inactivation a completely inactivated enzyme preparation containing 1.1 mol of covalently bound inhibitor/mol of protein was obtained by chromatography on a cellulosic matrix. The inactivated enzyme was digested with endoproteinase Glu-C and radioactive peptides purified by reversed-phase high performance liquid chromatography (HPLC). The affinity label was esterified exclusively to the gamma-carboxylate of Glu105 in the sequence Gly-Thr-Pro-Trp-Asp-Glu-Ile-Asp-Ile-Glu109. The sequence motif Glu-(Ile/Leu)-Asp-Ile is found in many glucanases and xylanases and may therefore serve to identify the catalytic nucleophile in beta-glycanases, which otherwise exhibit a low degree of sequence identity. The esterification of Glu105 by the affinity label abolished endoproteinase Glu-C-mediated hydrolysis of the Glu-Ile106 peptide bond. Identification of phenylthiohydantoin-Glu105 during automated sequence analysis was not possible unless the affinity label was liberated by prior base hydrolysis. These observations formed the basis for the development of a highly sensitive approach for the identification of catalytic carboxylates in polysaccharide hydrolases employing non-radioactive inhibitors, comparative HPLC mapping, electrospray mass spectrometry, and Edman degradation.     

Re-engineering specificity in 1,3-1, 4-β-glucanase to accept branched xyloglucan substrates

Family 16 carbohydrate active enzyme members Bacillus licheniformis 1,3-1,4-β-glucanase and Populus tremula x tremuloides xyloglucan endotransglycosylase (XET16-34) are highly structurally related but display different substrate specificities. Although the first binds linear gluco-oligosaccharides, the second binds branched xylogluco-oligosaccharides. Prior engineered nucleophile mutants of both enzymes are glycosynthases that catalyze the condensation between a glycosyl fluoride donor and a glycoside acceptor. With the aim of expanding the glycosynthase technology to produce designer oligosaccharides consisting of hybrids between branched xylogluco- and linear gluco-oligosaccharides, enzyme engineering on the negative subsites of 1,3-1,4-β-glucanase to accept branched substrates has been undertaken. Removal of the 1,3-1,4-β-glucanase major loop and replacement with that of XET16-34 to open the binding cleft resulted in a folded protein, which still maintained some β-glucan hydrolase activity, but the corresponding nucleophile mutant did not display glycosynthase activity with either linear or branched glycosyl donors. Next, point mutations of the 1,3-1,4-β-glucanase β-sheets forming the binding site cleft were mutated to resemble XET16-34 residues. The final chimeric protein acquired binding affinity for xyloglucan and did not bind β-glucan. Therefore, binding specificity has been re-engineered, but affinity was low and the nucleophile mutant of the chimeric enzyme did not show glycosynthase activity to produce the target hybrid oligosaccharides. Structural analysis by X-ray crystallography explains these results in terms of changes in the protein structure and highlights further engineering approaches toward introducing the desired activity.