Molecular engineering of a thermostable carbohydrate-binding module

Structure-function studies are frequently practiced on the very diverse group of natural carbohydrate-binding modules in order to understand the target recognition of these proteins. We have taken a step further in the study of carbohydrate-binding modules and created variants with novel binding properties by molecular engineering of one such molecule of known 3D-structure. A combinatorial library was created from the sequence encoding a thermostable carbohydrate-binding module, CBM4-2 from a Rhodothermus marinus xylanase, and the phage-display technology was successfully used for selection of variants with specificity towards different carbohydrate polymers (birchwood xylan, Avicel™, ivory nut mannan and recently also xyloglucan), as well as towards a glycoprotein (human IgG4). Our work not only generated a number of binders with properties that would suite a range of biotechnological applications, but analysis the selected binders also helped us to identify residues important for their specificities.     

Post-translational processing of modular xylanases from <Emphasis Type="Italic">Streptomyces</Emphasis> is dependent on the carbohydrate-binding module

Xylanases are very often modular enzymes composed of one or more catalytic domains and carbohydrate-binding modules (CBMs) connected by a flexible linker region. Usually, when these proteins are processed they lose their carbohydrate-binding capacity. Here, the role of the linker regions and cellulose- or xylan-binding domains in the processing of Xys1L from Streptomyces halstedii JM8 and Xyl30L from Streptomyces avermitilis UAH30 was studied. Xys1 variants with different linker lengths were tested, these being unable to avoid protein processing. Moreover, several fusion proteins between the Xys1 and Xyl30 domains were obtained and their proteolytic stability was studied. We demonstrate that CBM processing takes place even in the complete absence of the linker sequence. We also show that the specific carbohydrate module determines this cleavage in the proteins studied.     

The secondary substrate binding site of the <Emphasis Type="Italic">Pseudoalteromonas haloplanktis</Emphasis> GH8 xylanase is relevant for activity on insoluble but not soluble substrates

Previously, it has been demonstrated that the glycoside hydrolase family 8 xylanase from the psychrophylic bacterium Pseudoalteromonas haloplanktis (XPH) can bind substrate non-catalytically on the surface of its catalytic module. In the present study, the functional relevance of this secondary binding site (SBS) for the enzyme is investigated by site-directed mutagenesis and evaluation of activity and binding properties of mutant variants on a range of structurally different homoxylan and heteroxylan substrates. The SBS had an impact on the activity on insoluble substrates, whereas the activity on soluble substrates remained unaffected. Unexpectedly, the activity on a soluble oligomeric substrate was also affected for some mutants and results on a chromophoric polymeric model substrate were in contrast with the trends observed on the corresponding natural substrate. All in all, results show that the impact of the SBS on the activity of XPH is in part analogous to the functioning of some carbohydrate-binding modules in modular enzymes.     

Thermostable carbohydrate-binding modules in affinity chromatography

Affinity chromatography is routinely used mostly on a preparative scale to isolate different biomolecules such as proteins and carbohydrates. To this end a variety of proteins is in common use as ligands. To extend the arsenal of binders intended for separation of carbohydrates, we have explored the use of carbohydrate-binding modules (CBM) in affinity chromatography. The thermostable protein CBM4-2 and two variants (X-6 and A-6) thereof, selected from a newly constructed combinatorial library, were chosen for this study. The CBM4-2 predominantly binds to xylans but also crossreacts with glucose-based oligomers. The two CBM-variants X-6 and A-6 had been selected for binding to xylan and Avicel (a mixture of amorphous and microcrystalline cellulose), respectively. To assess the ability of these proteins to separate carbohydrates, they were immobilized to macroporous microparticulate silica and analyses were conducted at temperatures ranging from 25 to 65 degrees C. With the given set of CBM-variants, we were able to separate cello- and xylo-oligomers under isocratic conditions. The affinities of the CBMs for their targets were weak (in the mM-microM range) and by adjusting the column temperature we could optimize peak resolution and chromatographic retention times. The access to thermostable CBM-variants with diverse affinities and selectivities holds promise to be an efficient tool in the field of affinity chromatography for the separation of carbohydrates.     

Novel xylan-binding properties of an engineered family 4 carbohydrate-binding module

Molecular engineering of ligand-binding proteins is commonly used for identification of variants that display novel specificities. Using this approach to introduce novel specificities into CBMs (carbohydrate-binding modules) has not been extensively explored. Here, we report the engineering of a CBM, CBM4-2 from the Rhodothermus marinus xylanase Xyn10A, and the identification of the X-2 variant. As compared with the wild-type protein, this engineered module displays higher specificity for the polysaccharide xylan, and a lower preference for binding xylo-oligomers rather than binding the natural decorated polysaccharide. The mode of binding of X-2 differs from other xylan-specific CBMs in that it only has one aromatic residue in the binding site that can make hydrophobic interactions with the sugar rings of the ligand. The evolution of CBM4-2 has thus generated a xylan-binding module with different binding properties to those displayed by CBMs available in Nature.     

Characterization of a salt-tolerant xylanase from Thermoanaerobacterium saccharolyticum NTOU1

A xylanase gene was PCR-cloned from Thermoanaerobacterium saccharolyticum and expressed in Escherichia coli. The xylanase (XynA) consisted of a signal peptide, glycoside hydrolase family 10 domains, carbohydrate-binding modules, and surface layer homology domains. It was optimally active at 70–73°C and at pH 5–7. It had enhanced activity with NaCl with optimal activity at 0.4 M but was tolerant up to 2 M NaCl. The thermostable and salt-tolerant properties of this xylanase suggest that it may be useful for industrial applications.     

Modular organisation and functional analysis of dissected modular β-mannanase CsMan26 from Caldicellulosiruptor Rt8B.4

CsMan26 from Caldicellulosiruptor strain Rt8.B4 is a modular β-mannanase consisting of two N-terminal family 27 carbohydrate-binding modules (CBMs), followed by a family 35 CBM and a family 26 glycoside hydrolase catalytic module (mannanase). A functional dissection of the full-length CsMan26 and a comprehensive characterisation of the truncated derivatives were undertaken to evaluate the role of the CBMs. Limited proteolysis was used to define biochemically the boundaries of the different structural modules in CsMan26. The full-length CsMan26 and three truncated derivatives were produced in Escherichia coli, purified and characterised. The systematic removal of the CBMs resulted in a decrease in the optimal temperature for activity and in the overall thermostability of the derivatives. Kinetic experiments indicated that the presence of the mannan-specific family 27 CBMs increased the affinity of the enzyme towards the soluble galactomannan substrate but this was accompanied by lower catalytic efficiency. The full-length CsMan26 and its truncated derivatives were unable to hydrolyse mannooligosaccharides with degree of polymerisation (DP) of three or less. The major difference in the hydrolysis pattern of larger mannooligosaccharides (DP >3) by the derivatives was determined by their abilities to further hydrolyse the intermediate sugar mannotetraose.     

The X6 "thermostabilizing" domains of xylanases are carbohydrate-binding modules: structure and biochemistry of the Clostridium thermocellum X6b domain

Many polysaccharide-degrading enzymes display a modular structure in which a catalytic module is attached to one or more noncatalytic modules. Several xylanases contain a module of previously unknown function (termed "X6" modules) that had been implicated in thermostability. We have investigated the properties of two such "thermostabilizing" modules, X6a and X6b from the Clostridium thermocellumxylanase Xyn10B. These modules, expressed either as discrete entities or as their natural fusions with the catalytic module, were assayed, and their capacity to bind various carbohydrates and potentiate hydrolytic activity was determined. The data showed that X6b, but not X6a, increased the activity of the enzyme against insoluble xylan and bound specifically to xylooligosaccharides and various xylans. In contrast, X6a exhibited no affinity for soluble or insoluble forms of xylan. Isothermal titration calorimetry revealed that the ligand-binding site of X6b accommodates approximately four xylose residues. The protein exhibited K(d) values in the low micromolar range for xylotetraose, xylopentaose, and xylohexaose; 24 microM for xylotriose; and 50 microM for xylobiose. Negative DeltaH and DeltaS values indicate that the interaction of X6b with xylooligosaccharides and xylan is driven by enthalpic forces. The three-dimensional structure of X6b has been solved by X-ray crystallography to a resolution of 2.1 A. The protein is a beta-sandwich that presents a tryptophan and two tyrosine residues on the walls of a shallow cleft that is likely to be the xylan-binding site. In view of the structural and carbohydrate-binding properties of X6b, it is proposed that this and related modules be re-assigned as family 22 carbohydrate-binding modules.     

Carbohydrate recognition by an architecturally complex α-N-acetylglucosaminidase from Clostridium perfringens

CpGH89 is a large multimodular enzyme produced by the human and animal pathogen Clostridium perfringens. The catalytic activity of this exo-α-D-N-acetylglucosaminidase is directed towards a rare carbohydrate motif, N-acetyl-β-D-glucosamine-α-1,4-D-galactose, which is displayed on the class III mucins deep within the gastric mucosa. In addition to the family 89 glycoside hydrolase catalytic module this enzyme has six modules that share sequence similarity to the family 32 carbohydrate-binding modules (CBM32s), suggesting the enzyme has considerable capacity to adhere to carbohydrates. Here we suggest that two of the modules, CBM32-1 and CBM32-6, are not functional as carbohydrate-binding modules (CBMs) and demonstrate that three of the CBMs, CBM32-3, CBM32-4, and CBM32-5, are indeed capable of binding carbohydrates. CBM32-3 and CBM32-4 have a novel binding specificity for N-acetyl-β-D-glucosamine-α-1,4-D-galactose, which thus complements the specificity of the catalytic module. The X-ray crystal structure of CBM32-4 in complex with this disaccharide reveals a mode of recognition that is based primarily on accommodation of the unique bent shape of this sugar. In contrast, as revealed by a series of X-ray crystal structures and quantitative binding studies, CBM32-5 displays the structural and functional features of galactose binding that is commonly associated with CBM family 32. The functional CBM32s that CpGH89 contains suggest the possibility for multivalent binding events and the partitioning of this enzyme to highly specific regions within the gastrointestinal tract.     

The First Thermodynamic Characterization of β-1,3-Xylanase from a Marine Bacterium

Sequence analysis of β-1,3-xylanase (TxyA) from a marine bacterium, Alcaligenes sp. strain XY-234 implied that an xylan-binding module belonging to carbohydrate-binding module family 31 (TxyA-CBM) is separated from a catalytic module belonging to glycosyl hydrolase family 26 (TxyA-CM) by a putative glycine-rich linker [Okazaki, F., et al. (2002) J. Bacteriol. 184: 2399–2403]. In order to reveal the role of these structural features of TxyA, two modules, TxyA-CBM and TxyA-CM, were constructed, and those modules and full-length TxyA were characterized by thermodynamic studies. TxyA-CBM and TxyA-CM showed full reversible folding from denaturant-induced unfolded forms, exhibited higher thermodynamic stabilities. The conformational stability of both truncated modules is industrially desirable, as well as aiding the understanding of the enzymatic characterization of the two modules of β-1,3-xylanase separated by a long linker.     

Additional Carbohydrate-Binding Modules Enhance the Insoluble Substrate-Hydrolytic Activity of β-1,3-Glucanase from Alkaliphilic Nocardiopsis sp. F96

β-1,3-Glucanase (BglF) from Nocardiopsis sp. F96 is composed of only a catalytic domain. To improve the enzymatic properties of BglF, we attempted to construct chimeric enzymes consisting of BglF and some carbohydrate-binding modules, such as the C-terminal additional domain (CAD) and the N-terminal additional domain (NAD) of β-1,3-glucanase H from Bacillus circulans IAM1165 and the chitin-binding domain (ChBD) of chitinase from alkaliphilic Bacillus sp. J813. CAD-fused BglF (BglF-CAD), NAD-fused BglF (NAD-BglF), both NAD- and CAD-fused BglF (NAD-BglF-CAD) and ChBD-fused BglF (BglF-ChBD) were constructed and characterized. The addition of CAD caused increases in binding abilities and hydrolytic activities toward insoluble β-1,3-glucans. As well as BglF-CAD, the binding ability and hydrolytic activity of BglF-ChBD toward pachyman were also increased. The hydrolytic activity of BglF-CAD at pH 9–10 was higher than that of BglF. The relative activities of BglF-CAD and BglF-ChBD at around 50–70 °C were higher than that of BglF.     

Comparative Characteristics of Carbohydrate Binding by Lectins from Broad Bean,Pea, Common Vetch,and Lentil Seeds

Lectins from the seeds of broad bean (Vicia faba L.), pea (Pisum sativum L.), common vetch (V. sativa L.), and lentil (Lens culinaris Medik.) were isolated and purified by affinity chromatography. The hemagglutinating activity of lectins was most effectively inhibited by methyl--D-mannopyranoside, trehalose, and D-mannose. Other carbohydrate haptens, such as methyl--D-glucopyranoside, maltose, and alginic and D-glucuronic acids were less effective. Two lectins obtained from different lentil cultivars, unlike other lectins, had a relatively high affinity for melecitose, N-acetyl-D-glucosamine, L-sorbose, and sucrose. Furthermore, these lectins interacted with soluble starch. All the lectins examined had similar, but not identical, carbohydrate-binding properties. Because of their similar D-mannose/D-glucose specificity, these lectins interacted with lipopolysaccharides and exopolysaccharides of Rhizobium leguminosarum bv. viciae, root nodule bacteria that infect broad-bean, pea, common-vetch, and lentil plants with the formation of nitrogen-fixing symbiosis. However, owing to individual distinctions of carbohydrate-binding properties, these lectins showed a higher affinity for the polysaccharides of those microsymbionts within the R. leguminosarum bv. viciae species that were better specialized towards one or the other host plant from the cross inoculation group of legumes.     

Lactation-associated redistribution of the glial fibrillary acidic protein within the supraoptic nucleus

Summary Three clones of myeloproliferative virus (MPV)-transformed rat fibroblasts (NRK) with different growth properties and morphology were transplanted to athymic nude mice. Presence of carbohydrate-binding proteins was inferred by fluorescence microscopy using fluorescent, glycosylated markers. Salt and detergent extracts of tumors from this model system were fractionated under identical conditions on different sets of Sepharose columns, to which lactose, asialofetuin, melibiose, mannan and fucose had been covalently linked. Successive elution by chelating reagent and specific sugar resulted in isolation of the different Ca²⁺-dependent and Ca²⁺-independent endogenous carbohydrate-binding proteins that were assayable as agglutinins. In comparison, the different tumors displayed a pattern with qualitative and quantitative alterations. Since protein-carbohydrate interaction mediated by carbohydrate-binding proteins (lectins) is of importance for cognitive processes, it is remarkable that the pattern of membrane glycoproteins, isolated by affinity chromatography on resins with immobilized plant lectins, had also been found to reveal certain individual properties for receptors specific for peanut agglutinin (PNA) and Ulex europaeus agglutinin (UEA). These demonstrated differences within the system of protein-carbohydrate interaction suggest that endogenous lectins and their ligands have potential significance as markers defining a certain phenotype within this tumor model system.Dedicated to Prof. Dr. W. Lamprecht on the occasion of his 60th birthday     

Automated identification of RNA 3D modules with discriminative power in RNA structural alignments

Recent progress in predicting RNA structure is moving towards filling the ‘gap’ in 2D RNA structure prediction where, for example, predicted internal loops often form non-canonical base pairs. This is increasingly recognized with the steady increase of known RNA 3D modules. There is a general interest in matching structural modules known from one molecule to other molecules for which the 3D structure is not known yet. We have created a pipeline, metaRNAmodules, which completely automates extracting putative modules from the FR3D database and mapping of such modules to Rfam alignments to obtain comparative evidence. Subsequently, the modules, initially represented by a graph, are turned into models for the RMDetect program, which allows to test their discriminative power using real and randomized Rfam alignments. An initial extraction of 22 495 3D modules in all PDB files results in 977 internal loop and 17 hairpin modules with clear discriminatory power. Many of these modules describe only minor variants of each other. Indeed, mapping of the modules onto Rfam families results in 35 unique locations in 11 different families. The metaRNAmodules pipeline source for the internal loop modules is available at http://rth.dk/resources/mrm.     

Engineered xyloglucan specificity in a carbohydrate-binding module

The field of plant cell wall biology is constantly growing and consequently so is the need for more sensitive and specific probes for individual wall components. Xyloglucan is a key polysaccharide widely distributed in the plant kingdom in both structural and storage tissues that exist in both fucosylated and non-fucosylated variants. Presently, the only xyloglucan marker available is the monoclonal antibody CCRC-M1 that is specific to terminal alpha-1,2-linked fucosyl residues on xyloglucan oligo- and polysaccharides. As a viable alternative to searches for natural binding proteins or creation of new monoclonal antibodies, an approach to select xyloglucan-specific binding proteins from a combinatorial library of the carbohydrate-binding module, CBM4-2, from xylanase Xyn10A of Rhodothermus marinus is described. Using phage display technology in combination with a chemoenzymatic method to anchor xyloglucan to solid supports, the selection of xyloglucan-binding modules with no detectable residual wild-type xylan and beta-glucan-binding ability was achieved.     

Development of a selection system for the detection of L-ribose isomerase expressing mutants of <Emphasis Type="Italic">Escherichia coli</Emphasis>

L-Arabinose isomerase (E.C. 5.3.1.14) catalyzes the reversible isomerization between L-arabinose and L-ribulose and is highly selective towards L-arabinose. By using a directed evolution approach, enzyme variants with altered substrate specificity were created and screened in this research. More specifically, the screening was directed towards the identification of isomerase mutants with L-ribose isomerizing activity. Random mutagenesis was performed on the Escherichia coli L-arabinose isomerase gene (araA) by error-prone polymerase chain reaction to construct a mutant library. To enable screening of this library, a selection host was first constructed in which the mutant genes were transformed. In this selection host, the genes encoding for L-ribulokinase and L-ribulose-5-phosphate-4-epimerase were brought to constitutive expression and the gene encoding for the native L-arabinose isomerase was knocked out. L-Ribulokinase and L-ribulose-5-phosphate-4-epimerase are necessary to ensure the channeling of the formed product, L-ribulose, to the pentose phosphate pathway. Hence, the mutant clones could be screened on a minimal medium with L-ribose as the sole carbon source. Through the screening, two first-generation mutants were isolated, which expressed a small amount of L-ribose isomerase activity.     

Purification, characterization and modular organization of a cellulose-binding protein, CBP105, a processive β-1,4-endoglucanase from Cellulomonas flavigena

A cellulose-binding protein of 105 kDa (CBP105) from Cellulomonas flavigena was purified and its gene was cloned. CBP105 is a processive endoglucanase with maximum activity on carboxymethyl cellulose (CMC) at pH 7.5 and 60°C. Limited proteolysis suggested that CBP105 is composed of one catalytic domain (CD) and two carbohydrate-binding modules (CBM). The nucleotide sequence of the cbp105 gene (AY729806) indicates that CBP105 is a modular enzyme with a family 9 glycoside hydrolase CD linked to a family 3 CBM, two fibronectin III-like domains and a family 2 CBM. This structural organization may be responsible for CBP105 processive CMC degradation.     

Affinity electrophoresis for the identification and characterization of soluble sugar binding by carbohydrate-binding modules

Affinity electrophoresis was used to identify and quantify the interaction of carbohydrate-binding modules (CBMs) with soluble polysaccharides. Association constants determined by AE were in excellent agreement with values obtained by isothermal titration calorimetry and fluorescence titration. The method was adapted to the identification, study and characterization of mutant carbohydrate-binding modules with altered affinities and specificities. Competition affinity electrophoresis was used to monitor binding of small, soluble mono- and disaccharides to one of the modules.     

Identification of carbohydrate-binding proteins from mouse and human fibroblasts.

Three carbohydrate-binding proteins (Mr 35 000, 16 000 and 13 500) were isolated from extracts of mouse 3T3 fibroblasts by affinity chromatography on polyacrylamide beads to which was covalently bound the ligand 6-aminohexyl 4-beta-D-galactosyl-2-acetamido-2-deoxy-beta-D-glucopyranoside. None of these proteins bind to polyacrylamide beads coupled with either 6-aminohexanol or 6-aminohexyl beta-D-galactopyranoside. Therefore they appear to be carbohydrate-binding proteins specific for galactose-terminated glycoconjugates. A carbohydrate-binding protein was also purified from extracts of human foreskin fibroblasts. This protein (Mr 35000) may represent the human counterpart of the mouse protein of similar Mr and binding properties.     

Mode of operation and low-resolution structure of a multi-domain and hyperthermophilic endo-β-1,3-glucanase from Thermotoga petrophila

1,3-β-Glucan depolymerizing enzymes have considerable biotechnological applications including biofuel production, feedstock-chemicals and pharmaceuticals. Here we describe a comprehensive functional characterization and low-resolution structure of a hyperthermophilic laminarinase from Thermotoga petrophila (TpLam). We determine TpLam enzymatic mode of operation, which specifically cleaves internal β-1,3-glucosidic bonds. The enzyme most frequently attacks the bond between the 3rd and 4th residue from the non-reducing end, producing glucose, laminaribiose and laminaritriose as major products. Far-UV circular dichroism demonstrates that TpLam is formed mainly by beta structural elements, and the secondary structure is maintained after incubation at 90 °C. The structure resolved by small angle X-ray scattering, reveals a multi-domain structural architecture of a V-shape envelope with a catalytic domain flanked by two carbohydrate-binding modules.