The NodB domain of a multidomain xylanase from Cellulomonas fimi deacetylates acetylxylan

Molecular cloning and characterization of a novel xylanase from Microbacterium imperiale YD-01

Xylaneses are very common xylanolytic enzymes, which are widely used in food, papermaking, and other industries. In this study, a xylanase-encoding gene xyn1923, which encodes a protein of 1352 amino acids, was identified through the whole genome analysis of Microbacterium imperiale YD-01. Bioinformatics analysis showed that Xyn1923 only had maximum similarity of 37% with the reported xylanase from Alkalihalobacillus halodurans C-125, indicating that Xyn1923 was a novel xylanase. The enzymatic properties of Xyn1923 were systematically analyzed after purification. The results showed that the specific activity of the enzyme was 10.582 ± 0.413 U/mg, while the optimum pH and temperature of the enzyme were 7.0 and 70°C, respectively. The enzyme is stable in the pH range of 6.0-9.0, and the enzyme activity could maintain more than 85% of the original activity after 16 hr incubation at pH 9.0. The enzyme activity is relatively stable in the range of 30-60°C, and its enzyme activity could maintain more than 89% of the original activity after treatment at 60°C for 30 min. Low concentrations (≤1 mM) of Co²⁺ , Ba²⁺ , Fe²⁺ , and Fe³⁺ metal ions exerted a stimulatory effect on the activity of Xyn1923. And in contrast, high concentrations (≥2 mM) of the above metal ions inhibit the activity of Xyn1923. Mg²⁺ , Ag⁺ , Cu²⁺ , Ca²⁺ , Mn²⁺ , and Pb²⁺ ions showed a negative effect on the activity of Xyn1923. Enzyme kinetic studies showed that K_m and V_max values for xylan were 7.842 ± 0.538 mg/ml and 15.208 ± 0.822 U/mg, respectively. Xyn1923 was found to be a weakly alkaline thermophilic xylanase through an enzymatic property analysis. PRACTICAL APPLICATIONS: Xylanases are widely used in food and feed, biofuels, papermaking, and other industries. However, their use is limited by poor performance under the conditions of pH and temperature. Therefore, the discovery of xylanases with the capability of working efficiently at alkaline pH and high temperature is the priority for its industrial applications. In this study, a novel xylanase-encoding gene xyn1923 from Microbacterium imperiale YD-01 was cloned and heterologously expressed in Escherichia coli. Enzymatic properties of this novel xylanase were investigated, indicating that the robust thermal stability and alkali resistance of Xyn1923 make it a potential candidate for the food and paper industries.

Autodisplay of an endo-1,4-β-xylanase from Clostridium cellulovorans in Escherichia coli for xylans degradation

The goal of this work was the autodisplay of the endo β-1,4-xylanase (XynA) from Clostridium cellulovorans in Escherichia coli using the AIDA system to carry out whole-cell biocatalysis and hydrolysate xylans. For this, pAIDA-xynA vector containing a synthetic xynA gene was fused to the signal peptide of the toxin subunit B Vibro cholere (ctxB) and the auto-transporter of the synthetic aida gene, which encodes for the connector peptide and β-barrel of the auto-transporter (AT-AIDA). E. coli TOP10 cells were transformed and the biocatalyst was characterized using beechwood xylans as substrate. Optimal operational conditions were temperature of 55 °C and pH 6.5, and the Michaelis-Menten catalytic constants V_max and K_m were 149 U/g_DCW and 6.01 mg/mL, respectively. Xylanase activity was inhibited by Cu²⁺, Zn²⁺ and Hg²⁺ as well as EDTA, detergents, and organic acids, and improved by Ca²⁺, Co²⁺ and Mn²⁺ ions. Ca²⁺ ion strongly enhanced the xylanolytic activity up to 2.4-fold when 5 mM CaCl₂ were added. Also, Ca²⁺ improved enzyme stability at 60 and 70 °C. Results suggest that pAIDA-xynA vector has the ability to express functional xylanase to perform whole-cell biocatalysis in order to hydrolysate xylans from hemicellulose feedstock.

Cloning, Purification and Characterization of Acetyl Xylane Esterase from Anoxybacillus flavithermus DSM 2641(T) with Activity on Low Molecular-Weight Acetates

Family 4 carbohydrate esterases (CE-4) have deacetylate different forms of acetylated poly/oligosaccharides in nature. This family is recognized with a specific polysaccharide deacetylase domain assigned as NodB homology domain in their secondary structure. Most family 4 carbohydrate esterases have been structurally and biochemically characterized. However, this is the first study about the enzymological function of pdaB-like CE4s from thermophilic bacterium Anoxybacillus flavithermus DSM 2641(T). A. flavithermus WK1 genome harbors five putative CE4 family genes. One of them is 762 bp long and encodes a protein of 253 amino acids in length and it was used as reference sequence in this study. It was described as acetyl xylane esterase (AXE) in genome project and this AfAXE gene was amplified without signal sequence and cloned. The recombinant protein was expressed in E. coli BL21 (DE3), purified by nickel affinity chromatography and its purity was visualized on SDS-PAGE. The activity of the recombinant enzyme was shown by zymogram analysis with α-naphtyl acetate as a substrate. The enzyme was characterized spectrophotometrically using chromogenic p-nitrophenyl acetate. Optimum temperature and pH were determined as 50 °C and 7.5, respectively. Km and Vmax were determined as 0.43 mM and 3333.33 U/mg, respectively under optimum conditions. To our knowledge this is the first enzymological characterization of a pdaB-like family 4 carbohydrate esterase from the members of Anoxybacillus genus.

Microbial carbohydrate esterases deacetylating plant polysaccharides

Several plant polysaccharides are partially esterified with acetic acid. One of the roles of this modification is protection of plant cell walls against invading microorganisms. Acetylation of glycosyl residues of polysaccharides prevents hydrolysis of their glycosidic linkages by the corresponding glycoside hydrolases. In this way the acetylation also represents an obstacle of enzymatic saccharification of plant hemicelluloses to fermentable sugars which appears to be a hot topic of current research. We can eliminate this obstacle by alkaline extraction or pretreatment leading to saponification of ester linkages. However, this task has been accomplished in a different way in the nature. The acetyl groups became targets of microbial carbohydrate esterases that evolved to overcome the complexity of the plant cell walls and that cooperate with glycoside hydrolases in plant polysaccharide degradation. This article concentrates on enzymes deacetylating plant hemicelluloses excluding pectin. They are currently grouped in at least 8 families, specifically in CE families 1-7 and 16, originally assigned as acetylxylan esterases, the enzymes acting on hardwood acetyl glucuronoxylan and its fragments generated by endo-β-1,4-xylanases. There are esterases deacetylating softwood galactoglucomannan, but they have not been classified yet. The enzymes present in CE families 1-7 differ in structure and substrate and positional specificity. There are families behaving as endo-type and exo-type deacetylates, i.e. esterases deacetylating internal sugar residues of partially acetylated polysaccharides and also esterases deacetylating non-reducing end sugar residues in oligosaccharides. With one exception, the enzymes of all mentioned CE families belong to serine type esterases. CE family 4 harbors enzymes that are metal-dependent aspartic esterases. Three-dimensional structures have been solved for members of the first seven CE families, however, there is still insufficient knowledge about their substrate specificity and real physiological role. Current knowledge on catalytic properties of the selected families of CEs is summarized in this review. Some of the families are emerging also as new biocatalysts for regioselective acylation and deacylation of carbohydrates.

GH11 xylanases: Structure/function/properties relationships and applications

For technical, environmental and economical reasons, industrial demands for process-fitted enzymes have evolved drastically in the last decade. Therefore, continuous efforts are made in order to get insights into enzyme structure/function relationships to create improved biocatalysts. Xylanases are hemicellulolytic enzymes, which are responsible for the degradation of the heteroxylans constituting the lignocellulosic plant cell wall. Due to their variety, xylanases have been classified in glycoside hydrolase families GH5, GH8, GH10, GH11, GH30 and GH43 in the CAZy database. In this review, we focus on GH11 family, which is one of the best characterized GH families with bacterial and fungal members considered as true xylanases compared to the other families because of their high substrate specificity. Based on an exhaustive analysis of the sequences and 3D structures available so far, in relation with biochemical properties, we assess biochemical aspects of GH11 xylanases: structure, catalytic machinery, focus on their "thumb" loop of major importance in catalytic efficiency and substrate selectivity, inhibition, stability to pH and temperature. GH11 xylanases have for a long time been used as biotechnological tools in various industrial applications and represent in addition promising candidates for future other uses.

Cellulases of mesophilic microorganisms: cellulosome and noncellulosome producers

The cellulolytic activity of mesophilic bacteria and fungi is described, with special emphasis on the large extracellular enzyme complex called the cellulosome. The cellulosome is composed of a scaffolding protein, which is attached to various cellulolytic and hemicellulolytic enzymes, and this complex allows the organisms to degrade plant cell walls very efficently. The enzymes include a variety of cellulases, hemicellulases, and pectinases that work synergistically to degrade complex cell-wall molecules.

The vicinal hydroxyl group is prerequisite for metal activation of Clostridium thermocellum acetylxylan esterase

Positional specificity of NodB-like domain of a multidomain xylanase U from Clostridium thermocellum (CtAxe) was investigated. Of three monoacetates of 4-nitrophenyl beta-d-xylopyranoside the acetylxylan esterase domain showed a clear preference for the 2-acetate. Moreover, the enzyme was significantly activated by Co(2+). Acetylated methyl beta-d-xylopyranosides were deacetylated slightly better at position 3 than at position 2, suggesting that the enzyme binds the substrate with the small methyl aglycone also in the opposite orientation. Nevertheless, both positions 2 and 3 of methyl beta-d-xylopyranoside were deacetylated much faster in the presence of the activating metal ion. In contrast, replacement of the hydroxyl group at either of these positions with fluorine or hydrogen, as well as acetylation of both positions, abolished the enzyme activity, regardless the absence or the presence of Co(2+). Thus, the presence of the free vicinal hydroxyl group seems to be a prerequisite not only for an efficient deacetylation of position 2 or 3, but also for the activation of the enzyme with cobalt ion. The demonstrated involvement of the vicinal hydroxyl groups in the mechanism of deacetylation is in accord with 3-D structures of CtAxe as well as other CE4 metal-dependent deacetylases.

Identification of catalytically important amino acid residues of Streptomyces lividans acetylxylan esterase A from carbohydrate esterase family 4

Multiple sequence alignment of Streptomyces lividans acetylxylan esterase A and other carbohydrate esterase family 4 enzymes revealed the following conserved amino acid residues: Asp-12, Asp-13, His-62, His-66, Asp-130, and His-155. These amino acids were mutated in order to investigate a functional role of these residues in catalysis. Replacement of the conserved histidine residues by alanine caused significant reduction of enzymatic activity. Maintenance of ionizable carboxylic group in side chains of amino acids at positions 12, 13, and 130 seems to be necessary for catalytic efficiency. The absence of conserved serine excludes a possibility that the enzyme is a serine esterase, in contrast to acetylxylan esterases of carbohydrate esterase families 1, 5, and 7. On the contrary, total conservation of Asp-12, Asp-13, Asp-130, and His-155 along with dramatic decrease in enzyme activity of mutants of either of these residues lead us to a suggestion that acetylxylan esterase A from Streptomyces lividans and, by inference, other members of carbohydrate esterase family 4 are aspartic deacetylases. We propose that one component of the aspartate dyad/triad functions as a catalytic nucleophile and the other one(s) as a catalytic acid/base. The ester/amide bond cleavage would proceed via a double displacement mechanism through covalently linked acetyl-enzyme intermediate of mixed anhydride type.

Ferulic acid: an antioxidant found naturally in plant cell walls and feruloyl esterases involved in its release and their applications

Ferulic acid is the most abundant hydroxycinnamic acid in the plant world and maize bran with 3.1% (w/w) ferulic acid is one of the most promising sources of this antioxidant. The dehydrodimers of ferulic acid are important structural components in the plant cell wall and serve to enhance its rigidity and strength. Feruloyl esterases are a subclass of the carboxylic acid esterases that hydrolyze the ester bond between hydroxycinnamic acids and sugars present in plant cell walls and they have been isolated from a wide range of microorganisms, when grown on complex substrates such as cereal brans, sugar beet pulp, pectin and xylan. These enzymes perform a function similar to alkali in the deesterification of plant cell wall and differ in their specificities towards the methyl esters of cinnamic acids and ferulolylated oligosaccharides. They act synergistically with xylanases and pectinases and facilitate the access of hydrolases to the backbone of cell wall polymers. The applications of ferulic acid and feruloyl esterase enzymes are many and varied. Ferulic acid obtained from agricultural byproducts is a potential precursor for the production of natural vanillin, due to the lower production cost.

Unusual microbial xylanases from insect guts

Recombinant DNA technologies enable the direct isolation and expression of novel genes from biotopes containing complex consortia of uncultured microorganisms. In this study, genomic libraries were constructed from microbial DNA isolated from insect intestinal tracts from the orders Isoptera (termites) and Lepidoptera (moths). Using a targeted functional assay, these environmental DNA libraries were screened for genes that encode proteins with xylanase activity. Several novel xylanase enzymes with unusual primary sequences and novel domains of unknown function were discovered. Phylogenetic analysis demonstrated remarkable distance between the sequences of these enzymes and other known xylanases. Biochemical analysis confirmed that these enzymes are true xylanases, which catalyze the hydrolysis of a variety of substituted beta-1,4-linked xylose oligomeric and polymeric substrates and produce unique hydrolysis products. From detailed polyacrylamide carbohydrate electrophoresis analysis of substrate cleavage patterns, the xylan polymer binding sites of these enzymes are proposed.

Carbohydrate esterase family 4 enzymes: substrate specificity

The substrate specificity of selected enzymes classified under Carbohydrate Esterase family 4 (CE4) has been examined. Chitin deacetylase from Mucor rouxii and both a native and a truncated form of acetyl xylan esterase from Streptomyces lividans were found to be active on both xylan and several soluble chitinous substrates. Furthermore, the activities of all enzymes examined were significantly increased in the presence of Co(2+) when chitinous substrates were employed. However, the presence of this metal ion did not result in enhancing the activities of the enzymes when xylan was used as substrate. An acetyl xylan esterase from Bacillus pumilus, classified under Carbohydrate Esterase family 7, was found to be inactive towards all chitinous substrates tested. Finally, all enzymes examined were inactive towards cell wall peptidoglycan.

Xylanase and acetyl xylan esterase activities of XynA, a key subunit of the Clostridium cellulovorans cellulosome for xylan degradation

The Clostridium cellulovorans xynA gene encodes the cellulosomal endo-1,4-beta-xylanase XynA, which consists of a family 11 glycoside hydrolase catalytic domain (CD), a dockerin domain, and a NodB domain. The recombinant acetyl xylan esterase (rNodB) encoded by the NodB domain exhibited broad substrate specificity and released acetate not only from acetylated xylan but also from other acetylated substrates. rNodB acted synergistically with the xylanase CD of XynA for hydrolysis of acetylated xylan. Immunological analyses revealed that XynA corresponds to a major xylanase in the cellulosomal fraction. These results indicate that XynA is a key enzymatic subunit for xylan degradation in C. cellulovorans.

High-level production of recombinant Aspergillus niger cinnamoyl esterase (FAEA) in the methylotrophic yeast Pichia pastoris

The cDNA encoding Aspergillus niger cinnamoyl esterase (FAEA) with its native signal sequence was isolated by reverse transcriptase-polymerase chain reaction, sequenced, and expressed in Pichia pastoris. Secretion yields up to 300 mg l(-1) were obtained in buffered medium. The recombinant FAEA was purified to homogeneity using a one-step purification protocol and found to be identical to the native enzyme with respect to size, pI, immunoreactivity and N-terminal sequence. Specific activity, pH and temperature optimum, and kinetic parameters were also found similar to the native esterase. FAEA is thus the first fungal esterase efficiently produced using a heterologous system.

Evidence for synergy between family 2b carbohydrate binding modules in Cellulomonas fimi xylanase 11A

Glycoside hydrolases often contain multiple copies of noncatalytic carbohydrate binding modules (CBMs) from the same or different families. Currently, the functional importance of this complex molecular architecture is unclear. To investigate the role of multiple CBMs in plant cell wall hydrolases, we have determined the polysaccharide binding properties of wild type and various derivatives of Cellulomonas fimi xylanase 11A (Cf Xyn11A). This protein, which binds to both cellulose and xylan, contains two family 2b CBMs that exhibit 70% sequence identity, one internal (CBM2b-1), which has previously been shown to bind specifically to xylan and the other at the C-terminus (CBM2b-2). Biochemical characterization of CBM2b-2 showed that the module bound to insoluble and soluble oat spelt xylan and xylohexaose with K(a) values of 5.6 x 10(4), 1.2 x 10(4), and 4.8 x 10(3) M(-1), respectively, but exhibited extremely weak affinity for cellohexaose (<10(2) M(-1)), and its interaction with insoluble cellulose was too weak to quantify. The CBM did not interact with soluble forms of other plant cell wall polysaccharides. The three-dimensional structure of CBM2b-2 was determined by NMR spectroscopy. The module has a twisted "beta-sandwich" architecture, and the two surface exposed tryptophans, Trp 570 and Trp 602, which are in a perpendicular orientation with each other, were shown to be essential for ligand binding. In addition, changing Arg 573 to glycine altered the polysaccharide binding specificity of the module from xylan to cellulose. These data demonstrate that the biochemical properties and tertiary structure of CBM2b-2 and CBM2b-1 are extremely similar. When CBM2b-1 and CBM2b-2 were incorporated into a single polypeptide chain, either in the full-length enzyme or an artificial construct comprising both CBM2bs covalently joined via a flexible linker, there was an approximate 18-20-fold increase in the affinity of the protein for soluble and insoluble xylan, as compared to the individual modules, and a measurable interaction with insoluble acid-swollen cellulose, although the K(a) (approximately 6.0 x 10(4) M(-1)) was still much lower than for insoluble xylan (K(a) = approximately 1.0 x 10(6) M(-1)). These data demonstrate that the two family 2b CBMs of Cf Xyn11A act in synergy to bind acid swollen cellulose and xylan. We propose that the increased affinity of glycoside hydrolases for polysaccharides, through the synergistic interactions of CBMs, provides an explanation for the duplication of CBMs from the same family in some prokaryotic cellulases and xylanases.

Chitin deacetylases: new, versatile tools in biotechnology

Chitin deacetylases have been identified in several fungi and insects. They catalyse the hydrolysis of N-acetamido bonds of chitin, converting it to chitosan. Chitosans, which are produced by a harsh thermochemical procedure, have several applications in areas such as biomedicine, food ingredients, cosmetics and pharmaceuticals. The use of chitin deacetylases for the conversion of chitin to chitosan, in contrast to the presently used chemical procedure, offers the possibility of a controlled, non-degradable process, resulting in the production of novel, well-defined chitosan oligomers and polymers.

Three multidomain esterases from the cellulolytic rumen anaerobe Ruminococcus flavefaciens 17 that carry divergent dockerin sequences

Three enzymes carrying esterase domains have been identified in the rumen cellulolytic anaerobe Ruminococcus flavefaciens 17. The newly characterized CesA gene product (768 amino acids) includes an N-terminal acetylesterase domain and an unidentified C-terminal domain, while the previously characterized XynB enzyme (781 amino acids) includes an internal acetylesterase domain in addition to its N-terminal xylanase catalytic domain. A third gene, xynE, is predicted to encode a multidomain enzyme of 792 amino acids including a family 11 xylanase domain and a C-terminal esterase domain. The esterase domains from CesA and XynB share significant sequence identity (44%) and belong to carbohydrate esterase family 3; both domains are shown here to be capable of deacetylating acetylated xylans, but no evidence was found for ferulic acid esterase activity. The esterase domain of XynE, however, shares 42% amino acid identity with a family 1 phenolic acid esterase domain identified from Clostridum thermocellum XynZ. XynB, XynE and CesA all contain dockerin-like regions in addition to their catalytic domains, suggesting that these enzymes form part of a cellulosome-like multienzyme complex. The dockerin sequences of CesA and XynE differ significantly from those previously described in R. flavefaciens polysaccharidases, including XynB, suggesting that they might represent distinct dockerin specificities.

Feruloyl esterase activity of the Clostridium thermocellum cellulosome can be attributed to previously unknown domains of XynY and XynZ

The cellulosome of Clostridium thermocellum is a multiprotein complex with endo- and exocellulase, xylanase, beta-glucanase, and acetyl xylan esterase activities. XynY and XynZ, components of the cellulosome, are composed of several domains including xylanase domains and domains of unknown function (UDs). Database searches revealed that the C- and N-terminal UDs of XynY and XynZ, respectively, have sequence homology with the sequence of a feruloyl esterase of strain PC-2 of the anaerobic fungus Orpinomyces. Purified cellulosomes from C. thermocellum were found to hydrolyze FAXX (O-(5-O-[(E)-feruloyl]-alpha-L-arabinofuranosyl)-(1-->3)-O-beta-D- xyl opyranosyl-(1-->4)-D-xylopyranose) and FAX(3) (5-O-[(E)-feruloyl]-[O-beta-D-xylopyranosyl-(1-->2)]-O-alpha-L- arabinofuranosyl-[1-->3])-O-beta-D-xylopyranosyl-(1-->4)-D-xylopyranose) , yielding ferulic acid as a product, indicating that they have feruloyl esterase activity. Nucleotide sequences corresponding to the UDs of XynY and XynZ were cloned into Escherichia coli, and the expressed proteins hydrolyzed FAXX and FAX(3). The recombinant feruloyl esterase domain of XynZ alone (FAE(XynZ)) and with the adjacent cellulose binding domain (FAE-CBD(XynZ)) were characterized. FAE-CBD(XynZ) had a molecular mass of 45 kDa that corresponded to the expected product of the 1,203-bp gene. K(m) and V(max) values for FAX(3) were 5 mM and 12.5 U/mg, respectively, at pH 6.0 and 60 degrees C. PAX(3), a substrate similar to FAX(3) but with a p-coumaroyl group instead of a feruloyl moiety was hydrolyzed at a rate 10 times slower. The recombinant enzyme was active between pH 3 to 10 with an optimum between pH 4 to 7 and at temperatures up to 70 degrees C. Treatment of Coastal Bermuda grass with the enzyme released mainly ferulic acid and a lower amount of p-coumaric acid. FAE(XynZ) had similar properties. Removal of the 40 C-terminal amino acids, residues 247 to 286, of FAE(XynZ) resulted in protein without activity. Feruloyl esterases are believed to aid in a release of lignin from hemicellulose and may be involved in lignin solubilization. The presence of feruloyl esterase in the C. thermocellum cellulosome together with its other hydrolytic activities demonstrates a powerful enzymatic potential of this organelle in plant cell wall decomposition.

Molecular and biochemical characterization of two xylanase-encoding genes from Cellulomonas pachnodae

Two xylanase-encoding genes, named xyn11A and xyn10B, were isolated from a genomic library of Cellulomonas pachnodae by expression in Escherichia coli. The deduced polypeptide, Xyn11A, consists of 335 amino acids with a calculated molecular mass of 34,383 Da. Different domains could be identified in the Xyn11A protein on the basis of homology searches. Xyn11A contains a catalytic domain belonging to family 11 glycosyl hydrolases and a C-terminal xylan binding domain, which are separated from the catalytic domain by a typical linker sequence. Binding studies with native Xyn11A and a truncated derivative of Xyn11A, lacking the putative binding domain, confirmed the function of the two domains. The second xylanase, designated Xyn10B, consists of 1,183 amino acids with a calculated molecular mass of 124,136 Da. Xyn10B also appears to be a modular protein, but typical linker sequences that separate the different domains were not identified. It comprises a N-terminal signal peptide followed by a stretch of amino acids that shows homology to thermostabilizing domains. Downstream of the latter domain, a catalytic domain specific for family 10 glycosyl hydrolases was identified. A truncated derivative of Xyn10B bound tightly to Avicel, which was in accordance with the identified cellulose binding domain at the C terminus of Xyn10B on the basis of homology. C. pachnodae, a (hemi)cellulolytic bacterium that was isolated from the hindgut of herbivorous Pachnoda marginata larvae, secretes at least two xylanases in the culture fluid. Although both Xyn11A and Xyn10B had the highest homology to xylanases from Cellulomonas fimi, distinct differences in the molecular organizations of the xylanases from the two Cellulomonas species were identified.

A family IIb xylan-binding domain has a similar secondary structure to a homologous family IIa cellulose-binding domain but different ligand specificity

BACKGROUND

Many enzymes that digest polysaccharides contain separate polysaccharide-binding domains. Structures have been previously determined for a number of cellulose-binding domains (CBDs) from cellulases.

RESULTS

The family IIb xylan-binding domain 1 (XBD1) from Cellulomonas fimi xylanase D is shown to bind xylan but not cellulose. Its structure is similar to that of the homologous family IIa CBD from C. fimi Cex, consisting of two four-stranded beta sheets that form a twisted 'beta sandwich'. The xylan-binding site is a groove made from two tryptophan residues that stack against the faces of the sugar rings, plus several hydrogen-bonding polar residues.

CONCLUSIONS

The biggest difference between the family IIa and IIb domains is that in the former the solvent-exposed tryptophan sidechains are coplanar, whereas in the latter they are perpendicular, forming a twisted binding site. The binding sites are therefore complementary to the secondary structures of the ligands cellulose and xylan. XBD1 and CexCBD represent a striking example of two proteins that have high sequence similarity but a different function.

Molecular and biotechnological aspects of xylanases

Hemicellulolytic microorganisms play a significant role in nature by recycling hemicellulose, one of the main components of plant polysaccharides. Xylanases (EC 3.2.1.8) catalyze the hydrolysis of xylan, the major constituent of hemicellulose. The use of these enzymes could greatly improve the overall economics of processing lignocellulosic materials for the generation of liquid fuels and chemicals. Recently cellulase-free xylanases have received great attention in the development of environmentally friendly technologies in the paper and pulp industry. In microorganisms that produce xylanases low molecular mass fragments of xylan and their positional isomers play a key role in regulating its biosynthesis. Xylanase and cellulase production appear to be regulated separately, although the pleiotropy of mutations, which causes the elimination of both genes, suggests some linkage in the synthesis of the two enzymes. Xylanases are found in a cornucopia of organisms and the genes encoding them have been cloned in homologous and heterologous hosts with the objectives of overproducing the enzyme and altering its properties to suit commercial applications. Sequence analyses of xylanases have revealed distinct catalytic and cellulose binding domains, with a separate non-catalytic domain that has been reported to confer enhanced thermostability in some xylanases. Analyses of three-dimensional structures and the properties of mutants have revealed the involvement of specific tyrosine and tryptophan residues in the substrate binding site and of glutamate and aspartate residues in the catalytic mechanism. Many lines of evidence suggest that xylanases operate via a double displacement mechanism in which the anomeric configuration is retained, although some of the enzymes catalyze single displacement reactions with inversion of configuration. Based on a dendrogram obtained from amino acid sequence similarities the evolutionary relationship between xylanases is assessed. In addition the properties of xylanases from extremophilic organisms have been evaluated in terms of biotechnological applications.

Structure and function analysis of Pseudomonas plant cell wall hydrolases

Hydrolysis of the major structural polysaccharides of plant cell walls by the aerobic soil bacterium Pseudomonas fluorescens subsp. cellulosa is attributable to the production of multiple extracellular cellulase and hemicellulase enzymes, which are the products of distinct genes belonging to multigene families. Cloning and sequencing of individual genes, coupled with gene sectioning and functional analysis of the encoded proteins have provided a detailed picture of structure/function relationships and have established the cellulase-hemicellulase system of P. fluorescens subsp. cellulosa as a model for the plant cell wall degrading enzyme systems of aerobic cellulolytic bacteria. Cellulose- and xylan-degrading enzymes produced by the pseudomonad are typically modular in structure and contain catalytic and noncatalytic domains joined together by serine-rich linker sequences. The cellulases include a cellodextrinase; a beta-glucan glucohydrolase and multiple endoglucanases, containing catalytic domains belonging to glycosyl hydrolase families 5, 9, and 45; and cellulose-binding domains of families II and X, both of which are present in each enzyme. Endo-acting xylanases, with catalytic domains belonging to families 10 and 11, and accessory xylan-degrading enzymes produced by P. fluorescens subsp. cellulosa contain cellulose-binding domains of families II, X, and XI, which act by promoting close contact between the catalytic domain of the enzyme and its target substrate. A domain homologous with NodB from rhizobia, present in one xylanase, functions as a deacetylase. Mananase, arabinanase, and galactanase produced by the pseudomonad are single domain enzymes. Crystallographic studies, coupled with detailed kinetic analysis of mutant forms of the enzyme in which key residues have been altered by site-directed mutagenesis, have shown that xylanase A (family 10) has 8-fold alpha/beta barrel architecture, an extended substrate-binding cleft containing at least six xylose-binding pockets and a calcium-binding site that protects the enzyme from thermal inactivation, thermal unfolding, and attack by proteinases. Kinetic studies of mutant and wild-type forms of a mannanase and a galactanase from P. fluorescens subsp. cellulosa have enabled the catalytic mechanisms and key catalytic residues of these enzymes to be identified.

Action of acetylxylan esterase from Trichoderma reesei on acetylated methyl glycosides

Substrate specificity of purified acetylxylan esterase (AcXE) from Trichoderma reesei was investigated on partially and fully acetylated methyl glycopyranosides. Methyl 2,3,4-tri-O-acetyl-beta-D-xylopyranoside was deacetylated at positions 2 and 3, yielding methyl 4-O-acetyl-beta-D-xylopyranoside in almost 90% yield. Methyl 2,3-di-O-acetyl beta-D-xylopyranoside was deacetylated at a rate similar to the fully acetylated derivative. The other two diacetates (2,4- and 3,4-), which have a free hydroxyl group at either position 3 or 2, were deacetylated one order of magnitude more rapidly. Thus the second acetyl group is rapidly released from position 3 or 2 after the first acetyl group is removed from position 2 or 3. The results strongly imply that in degradation of partially acetylated beta-1,4-linked xylans, the enzyme deacetylates monoacetylated xylopyranosyl residues more readily than di-O-acetylated residues. The T. reesei AcXE attacked acetylated methyl beta-D-glucopyranosides and beta-D-mannopyranosides in a manner similar to the xylopyranosides.