Xylan deposition on secondary wall of Fagus crenata fiber

Summary. Delignified and/or xylanase-treated secondary walls of Fagus crenata fibers were examined by field emission scanning electron microscopy. Microfibrils with a smooth surface were visible in the innermost surface of the differentiating fiber secondary wall. There was no ultrastructural difference between control and delignified sections, indicating that lignin deposition had not started in the innermost surface of the cell wall. There was no ultrastructural difference between control and xylanase-treated sections. Microfibrils on the outer part of the differentiating secondary wall surface had globular substances in delignified sections. These globular substances disappeared following xylanase treatment, indicating that these globules are xylan. The globular substances were not visible near the inner part of the differentiating secondary wall but gradually increased toward the outer part of the secondary wall, indicating that xylan penetrated into the cell wall and continuously accumulated on the microfibrils. Mature-fiber secondary walls were also examined by field emission scanning electron microscopy. Microfibrils were not apparent in the secondary wall in control specimens. Microfibrils with many globular substances were observed in the delignified specimens. Following xylanase treatment, the microfibrils had a smooth surface without any globules, indicating that the globular substance is xylan. These results suggest that cellulose microfibrils synthesized on the plasma membrane are released into the innermost surface of the secondary wall and coated with a thin layer of xylan. Successive deposition of xylan onto the cell wall increases the microfibril diameter. The large amounts of xylan that accumulated on microfibrils appear globular but are covered with lignin after they are deposited. Received February 20, 2001/Accepted September 1, 2001     

Biochemical properties of xylanases from a thermophilic fungus,Melanocarpus albomyces, and their action on plant cell walls

Melanocarpus albomyces, a thermophilic fungus isolated from compost by enrichment culture in a liquid medium containing sugarcane bagasse, produced cellulase-free xylanase in culture medium. The fungus was unusual in that xylanase activity was inducible not only by hemicellulosic material but also by the monomeric pentosan unit of xylan but not by glucose. Concentration of bagasse-grown culture filtrate protein followed by size-exclusion and anion-exchange chromatography separated four xylanase activities. Under identical conditions of protein purification, xylanase I was absent in the xylose-grown culture filtrate. Two xylanase activities, a minor xylanase IA and a major xylanase IIIA, were purified to apparent homogeneity from bagasse-grown cultures. Both xylanases were specific forβ-1,4 xylose-rich polymer, optimally active, respectively, at pH 6.6 and 5.6, and at 65°C. The xylanases were stable between pH 5 to 10 at 50°C for 24 h. Xylanases released xylobiose, xylotriose and higher oligomers from xylans from different sources. Xylanase IA had a M_r of 38 kDa and contained 7% carbohydrate whereas xylanase IIIA had a M_r of 24 kDa and no detectable carbohydrate. The K_m for larchwood xylan (mg ml⁻¹) and V_max (μmol xylose min⁻¹ mg⁻¹ protein) of xylanase IA were 0.33 and 311, and of xylanase IIIA 1.69 and 500, respectively. Xylanases IA, II and IIIA showed no synergism in the hydrolysis of larchwood glucuronoxylan or oat spelt and sugarcane bagasse arabinoxylans. They had different reactivity on untreated and delignified bagasse. The xylanases were more reactive than cellulase on delignified bagasse. Simultaneous treatment of delignified bagasse by xylanase and cellulase released more sugar than individual enzyme treatments. By contrast, the primary cell walls of a plant, particularly from the region of elongation, were more susceptible to the action of cellulase than xylanase. The effects of xylanase and cellulase on plant cell walls were consistent with the view that hemicellulose surrounds cellulose in plant cell walls.     

The Extracellular Xylan Degradative System in Clostridium cellulolyticum Cultivated on Xylan: Evidence for Cell-Free Cellulosome Production

In this study, we demonstrate that the cellulosome of Clostridium cellulolyticum grown on xylan is not associated with the bacterial cell. Indeed, the large majority of the activity (about 90%) is localized in the cell-free fraction when the bacterium is grown on xylan. Furthermore, about 70% of the detected xylanase activity is associated with cell-free high-molecular-weight complexes containing avicelase activity and the cellulosomal scaffolding protein CipC. The same repartition is observed with carboxymethyl cellulase activity. The cellulose adhesion of xylan-grown cells is sharply reduced in comparison with cellulose-grown cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis revealed that cellulosomes derived from xylan- and cellulose-grown cells have different compositions. In both cases, the scaffolding protein CipC is present, but the relative proportions of the other components is dramatically changed depending on the growth substrate. We propose that, depending on the growth substrate, C. cellulolyticum is able to regulate the cell association and cellulose adhesion of cellulosomes and regulate cellulosomal composition.     

Cellulase-poor xylanases produced by Trichoderma reesei RUT C-30 on hemicellulose substrates

Hemicellulose components from industrial viscose fibre production are characterized by a lower cellulose content than commercial xylan and the presence of a carboxylic acid fraction originating from the alkaline degradation of carbohydrates during the process. This substrate, after neutralization, can be used by Trichoderma reesei RUT C-30 for the production of cellulase-poor xylanases, useful for the pulp and paper industry. The yields of xylanase ranged up to almost 400 units/ml, with a ratio of carboxymethylcellulase/xylanase of less than 0.015. This crude xylanase enzyme mixture was shown to be superior to that obtained on beech-wood xylan when used for bleaching and, particularly, upgrading of hard-wood chemical pulp by selective removal of the xylan components. Biochemical studies indicate that the low cellulase production by T. reesei grown on these waste hemicelluloses is the result of a combination of at least three factors: (a) the comparatively low content of cellulose in these hemicellulosic wastes, (b) the inhibitory action of the carboxylic acid fraction present in the hemicellulosic wastes on growth and sporulation of T. reesei, and (c) the use of a mycelial inoculum that is unable to initiate the attack on the cellulose components within the carbon source. Correspondence to: G. Gamerith     

A new role for veratryl alcohol: regulation of synthesis of lignocellulose-degrading enzymes in the ligninolytic ascomyceteous fungus, Botryosphaeria sp.; influence of carbon source

A new physiological role for veratryl alcohol in fungi important in the biodegradation of the lignified plant cell wall is presented. Botryosphaeria sp., grown on starch, pectin, cellulose or xylan produced amylase, pectinase, cellulase, xylanase and laccase, whereas glucose and xylose repressed the synthesis of cellulase and xylanase, but not laccase. When cultured on each of these substrates in the presence of veratryl alcohol, laccase activity increased but the activities of amylase, pectinase, cellulase and xylanase significantly decreased. Basal medium containing softwood kraft lignin in the presence of veratryl alcohol induced laccases above constitutive levels. Ethyl alcohol also stimulated laccase production.     

Cellulose and xylan degrading enzymes of Fusarium avenaceum

It was found that crude preparation obtained from the culture medium of Fusarium avenaceum degraded cellulose and xylan. After chromatography on CM-Sepharose CL-6B of this preparation six fraction were obtained. The eluted fractions II and V showed xylanase activity, fraction IV — cellulase activity and fraction III — xylanase and cellulase activity. The end products of xylan hydrolysis by all xylanase fractions (II, III, V) were xylobiose, xylose, xylotriose and xylotetrose. The end products of cellulose hydrolysis by fractions III and IV was cellobiose, glucose and cellotriose. The data from gel filtration on Sephacryl S-200 indicated a molecular weight of more than 250,000 for both cellulase IV and xylanase V. After gel filtration in the presence of urea disaggregation of those high molecular xylanase and cellulase particles was observed. Xylanase II in difference from the other fractions contained higher amount of sugar. Digestion of fraction II with cellulase-hemicellulase preparation from Phoma hibernica decreased the content of sugar from 17% to 8%, but did not change its enzymatic properties. Cellulase IV as well as xylanase V were inactivated by N-bromosuccinimide, 2-hydroxy-5-nitrobenzyl bromide and tetranitromethane, hence it is suggested that tryptophan and tyrosine are the essential for the activity of these enzymes.     

Colloidal Gold Cytochemistry of Endo-1,4-beta-Glucanase, 1,4-beta-D-Glucan Cellobiohydrolase, and Endo-1,4-beta-Xylanase: Ultrastructure of Sound and Decayed Birch Wood

Colloidal gold coupled to endo-1,4-beta-glucanase II (EG II) and 1,4-beta-D-glucan cellobiohydrolase I (CBH I), isolated from Trichoderma reesei (QM9414), and endo-1,4-beta-xylanase from Aureobasium pullulans (NRRLY-2311-1) was used successfully to determine the ultrastructural localization of cellulose and xylan in sound birch wood. In addition, these enzyme-gold complexes demonstrated the distribution of cellulose and xylan after decay by three white rot fungi, Phanerochaete chrysosporium, Phellinus pini, and Trametes versicolor, and one brown rot fungus, Fomitopis pinicola. Transverse sections of sound wood showed that EG II was localized primarily on the S(1) layer of the secondary wall, whereas CBH I labeled all layers of the secondary wall. Oblique sections showed a high concentration of gold labeling, using EG II or CBH I. Preference for the sides of the microfibrillar structure was observed for both EG II and CBH I, whereas only CBH I had a specificity for the cut ends of microfibrils. Labeling with the xylanase-gold complex occurred primarily in the inner regions of the S(2) layer, S(1), and the middle lamella. In contrast, little labeling occurred in the middle lamella with EG II or CBH I. Intercellular regions within the cell corners of the middle lamella were less electron dense and labeled positively when EG II- and xylanase-gold were used. Wood decayed by P. chrysosporium or P. pini was delignified, and extensive degradation of the middle lamella was evident. The remaining secondary walls labeled with EG II and CBH I, but little labeling was found with the xylanase-gold complex. Wood decayed by T. versicolor was nonselective, and erosion of all cell wall layers was apparent. Remaining wall layers near sites of erosion labeled with both EG II and CBH I. Erosion troughs that reached the S(1) layer or the middle lamella had less xylanase-gold labeling in the adjacent cell wall that remained. Brown-rotted wood had very low levels of gold particles present in sections treated with EG II or xylanase. Labeling with CBH I had the lowest concentrations in the S(2) layer near cell lumina and corresponded to sites with the most extensive degradation.     

Simultaneous production and induction of cellulolytic and xylanolytic enzymes in aStreptomyces sp.

Extracellular cellulolytic and xylanolytic enzymes ofStreptomyces sp. EC22 were produced during submerged fermentation. The cell-free culture supernatant of the streptomycete grown on microcrystalline cellulose contained enzymes able to depolymerize both crystalline and soluble celluloses and xylans. Higher cellulase and xylanase activities were found in the cell-free culture supernatant of the strain when grown on microcrystalline cellulose than when grown on xylan. Total cellulase and endoglucanase [carboxymethyl-cellulase (CMCase)] activities reached maxima after 72 h and xylanase activity was maximal after 60h. Temperature and pH optima were 55°C and 5.0 for CMCase activity and 60°C and 5.5 for total crystalline cellulase and xylanase activities. At 80°C, approximate half-lives of the enzymes were 37, 81 and 51 min for CMCase, crystalline cellulose depolymerization and xylanase, respectively.     

Cellulose- and xylan-degrading thermophilic anaerobic bacteria from biocompost

Nine thermophilic cellulolytic clostridial isolates and four other noncellulolytic bacterial isolates were isolated from self-heated biocompost via preliminary enrichment culture on microcrystalline cellulose. All cellulolytic isolates grew vigorously on cellulose, with the formation of either ethanol and acetate or acetate and formate as principal fermentation products as well as lactate and glycerol as minor products. In addition, two out of nine cellulolytic strains were able to utilize xylan and pretreated wood with roughly the same efficiency as for cellulose. The major products of xylan fermentation were acetate and formate, with minor contributions of lactate and ethanol. Phylogenetic analyses of 16S rRNA and glycosyl hydrolase family 48 (GH48) gene sequences revealed that two xylan-utilizing isolates were related to a Clostridium clariflavum strain and represent a distinct novel branch within the GH48 family. Both isolates possessed high cellulase and xylanase activity induced independently by either cellulose or xylan. Enzymatic activity decayed after growth cessation, with more-rapid disappearance of cellulase activity than of xylanase activity. A mixture of xylan and cellulose was utilized simultaneously, with a significant synergistic effect observed as a reduction of lag phase in cellulose degradation.     

Xylanase and cellulase of fungus Cerrena unicolor VKM F-3196: Production,properties, and applications for the saccharification of plant material

Under the conditions of submerged cultivation in a medium containing microcrystalline cellulose, the Cerrena unicolor VKM F-3196 basidiomycete is capable of producing xylanase and cellulase. Electrophoretically homogeneous cellulase and xylanase were obtained using ion exchange and hydrophobic chromatography. The molecular weight of both cellulase and xylanase was ～44 kDa. It was shown that xylanase catalyzed the hydrolysis of xylan with the production of xylose, xylobiose, and xylotetrose and it exhibited properties of endoxylanases. Cellulase hydrolyzed carboxymethylcellulose, xylan, and microcrystalline cellulose with the formation of cellotriose and cellotetraose. For both enzymes, the pH optimum was ～4.0. The enzymes exhibited moderate thermostability: xylanase retained 35% of the initial activity for 1 h at 60°C; cellulase, 10% under the same conditions. Xylanase, cellulose, and a mixture of these enzymes saccharified plant material (wheat, rye, wheat middling, and oat), indicating the possible use of these enzymes in biotechnology.     

Cellulase and xylanase activities in higher basidiomycetes.

Extracellular carboxymethylcellulase, xylanase, beta-glucosidase, and beta-xylosidase activities of four cultures of higher basidial fungi were studied in relation to the source of carbon in the nutrient medium. It was shown that beta-glucosidases and beta-xylosidases of all basidiomycetes and cellulases and xylanases of Pholiota aurivella IBR437 and Gloeophyllum saepiarium IBR155, the causal agents of wood brown rot, are constitutive enzymes; however, their activities depend on the source of carbon in the growth medium. Cellulases and xylanases of Coriolus pubescens IBR663 and Lentinus tigrinus IBR100 degrading wood through white rot are inducible enzymes. The synthesis of cellulases and xylanases was induced upon fungal growth on media containing crystalline cellulose and plant raw materials; carboxymethylcellulose and xylan were less effective. The induction of C. pubescens IBR663 cellulase and xylanase was observed when avicel was added to the culture growing on a mannitol-containing medium. Glucose at a concentration of 0.2-0.8% caused catabolite repression of C. pubescens IBR663 cellulase and xylanase. After utilization of glucose, leading to a decrease in its concentration below 0.1%, the synthesis of enzymes was resumed. These data indicate that the synthesis of cellulases and xylanases in the examined macromycetes is under common regulatory control.     

Hydrolysis of different chain length xylooliogmers by cellulase and hemicellulase

Commercial cellulase complexes produced by cellulolytic fungi contain enzyme activities that are capable of hydrolyzing non-cellulosic polysaccharides in biomass, primarily hemicellulose and pectins, in addition to cellulose. However, xylanase activities detected in most commercial enzyme preparations have been shown to be insufficient to completely hydrolyze xylan, resulting in high xylooligomer concentrations remaining in the hydrolysis broth. Our recent research showed that these xylooligomers are stronger inhibitors of cellulase activity than others have previously established for glucose and cellobiose, making their removal of great importance. In this study, a HPLC system that can measure xylooligomers with degrees of polymerization (DP) up to 30 was applied to assess how Spezyme CP cellulase, Novozyme 188 β-glucosidase, Multifect xylanase, and non-commercial β-xylosidase enzymes hydrolyze different chain length xylooligomers derived from birchwood xylan. Spezyme CP cellulase and Multifect xylanase partially hydrolyzed high DP xylooligomers to lower DP species and monomeric xylose, while β-xylosidase showed the strongest ability to degrade both high and low DP xylooligomers. However, about 10-30% of the higher DP xylooligomers were difficult to be breakdown by cellulase or xylanase and about 5% of low DP xylooligomers (mainly xylobiose) proved resistant to hydrolysis by cellulase or β-glucosidase, possibly due to low β-xylosidase activity in these enzymes and/or the precipitation of high DP xylooligomers.     

Synergistic effects of cellulosomal xylanase and cellulases from Clostridium cellulovorans on plant cell wall degradation

Plant cell walls are comprised of cellulose and hemicellulose and other polymers that are intertwined, and this complex structure presents a barrier to degradation by pure cellulases or hemicellulases. In this study, we determined the synergistic effects on corn cell wall degradation by the action of cellulosomal xylanase XynA and cellulosomal cellulases from Clostridium cellulovorans. XynA minicellulosomes and cellulase minicellulosomes were found to degrade corn cell walls synergistically but not purified substrates such as xylan and crystalline cellulose. The mixture of XynA and cellulases at a molar ratio of 1:2 showed the highest synergistic effect of 1.6 on corn cell wall degradation. The amounts both of xylooligosaccharides and cellooligosaccharides liberated from corn cell walls were increased by the synergistic action of XynA and cellulases. Although synergistic effects on corn cell wall degradation were found in simultaneous reactions with XynA and cellulases, no synergistic effects were observed in sequential reactions. The possible mechanism of synergism between XynA and cellulases is discussed.     

Microfibrillar structure of growing cell wall in a coenocytic green alga,Boergesenia forbesii

A fine structure of cell wall lamellae in a coenocytic green algaBoergesenia forbesii was examined by electron microscopy. The wall has a polylamellate structure containing cellulose microfibrils 25 to 30 nm in diameter. The outer surface of the cell was covered by a thin structureless lamella, underneath which existed a lamella containing randomly-oriented microfibrils. The major part of the wall consisted of two types of lamellae, multifibrillar lamella and a transitional, matrix-rich one. In the former, microfibrils were densely arranged more or less parallel with each other. In the transitional lamella, existing between the multifibrillar ones, the microfibril orientation shifted about 30° within the layer. The fibril orientation also shifted 30° between adjacent transitional and multifibrillar layers, and consequently the microfibril orientation in the neighboring multifibrillar layers shifted 90°. It was concluded that the orientation rotated counterclockwise when observed from inside the cell. Each lamella in the thallus wall become thinner with cell expansion, but no reorientation of microfibrils in the outer old layers was observed. In the rhizoid, the outer lamellae sloughed off with the tip growth.     

Production of cellulase enzymes during the solid-state fermentation of empty palm fruit bunch fiber

Penicillium verruculosum COKE4E is a fungal strain isolated from bituminous coal. The microorganism cultivated in a minimal medium supplemented with Avicel, carboxymethylcellulose, and oat spelt xylan produced cellulase enzymes as exhibiting carboxymethylcellulase (CMCase), Avicelase, xylanase, and cellobiosidase activities. In this study, the productivity of the extracellular enzymes in the strain was evaluated by using empty palm fruit bunch fiber (EPFBF), a lignocellulosic biomass, as a substrate for solid-state bioconversion. The highest cellulase activities were observed after 6 days of fermentation at pH 6.0 and 30 °C. The enzymes were secreted as cellulosomes for the degradation of EPFBF as a sole carbon source. Focused ion beam analysis showed that P. verruculosum COKE4E produced cellulolytic enzymes that were able to effectively biodegrade EPFBF during solid-state fermentation. In this process, 6.5 U of CMCase, 6.8 U of Avicelase, and 8.8 U of xylanase per gram of dry solid EPFBF were produced. These results demonstrate that EPFBF may be a potential raw material in solid-state fermentation for the production of cellulase enzymes to be used for biofuel production.     

Optimization of enzyme complexes for lignocellulose hydrolysis

The ability of a commercial Trichoderma reesei cellulase preparation (Celluclast 1.5L), to hydrolyze the cellulose and xylan components of pretreated corn stover (PCS) was significantly improved by supplementation with three types of crude commercial enzyme preparations nominally enriched in xylanase, pectinase, and beta-glucosidase activity. Although the well-documented relief of product inhibition by beta-glucosidase contributed to the observed improvement in cellulase performance, significant benefits could also be attributed to enzymes components that hydrolyze non-cellulosic polysaccharides. It is suggested that so-called "accessory" enzymes such as xylanase and pectinase stimulate cellulose hydrolysis by removing non-cellulosic polysaccharides that coat cellulose fibers. A high-throughput microassay, in combination with response surface methodology, enabled production of an optimally supplemented enzyme mixture. This mixture allowed for a approximately twofold reduction in the total protein required to reach glucan to glucose and xylan to xylose hydrolysis targets (99% and 88% conversion, respectively), thereby validating this approach towards enzyme improvement and process cost reduction for lignocellulose hydrolysis.     

Effect of pH on production of xylanase by Trichoderma reesei on xylan- and cellulose-based media

Trichoderma reesei VTT-D-86271 (Rut C-30) was cultivatedon media based on cellulose and xylan as the main carbon source in fermentors with different pH minimum controls. Production of xylanase was favoured by a rather high pH minimum control between 6.0 and 7.0 on both cellulose- and xylan-based media. Although xylanase was produced efficiently on cellulose as well as on xylan as the carbon source, significant production of cellulose was observed only on the cellulose-based medium and best production was at lower pH (4.0 minimum). Production of xylanase at pH 7.0 was shown to be dependent on the nature of the xylan in the cultivation medium but was independent of other organic components. Best production of xylanase was observed on insoluble, unsubstituted beech xylan at pH 7.0. Similar results were obtained in laboratory and pilot (200-l) fermentors. Downstream processing of the xylanase-rich, low-cellulose culture filtrate presented no technical problems despite apparent autolysis of the fungus at the high pH. Enzyme produced in the 200-l pilot fermentor was shown to be suitable for use in enzyme-aided bleaching of kraft pulp. Due to the high xylanase/cellulase ratio of enzyme activities in the culture filtrate, pretreatment for removal of cellulase activity prior to pulp bleaching was unnecessary. Correspondence to: M. J. Bailey     

Cloning and Characterizing the Thermophilic and Detergent Stable Cellulase CelMytB from Saccharophagus sp. Myt-1

We previously isolated and reported a second species of the Saccharophagus genus, Saccharophagus sp. strain Myt-1. In the present study, a cellulase gene (celMytB) from the genomic DNA of Myt-1 was cloned and characterized. The DNA sequence fragment contained an open reading frame of 1,893 bp that encoded a protein of 631 amino acids with an estimated molecular mass of 66.8 kDa. The deduced protein, CelMytB, had a catalytic domain that contained a conserved signature sequence (VIYEIYNEPL) of glycosyl hydrolase family 5 and a CBM6 cellulose binding module. CelMytB showed optimal activity at 55 °C and pH 6.5, which is similar to the optimal temperature and pH profile of cel5H, an endoglucanase from the closely related S. degradans 2-40. However, the cellulase (degradation of soluble cellulose) and avicelase (degradation of crystalline cellulose) activities of CelMytB were about 3-fold and 100-fold higher, respectively, than the equivalent activities of cel5H. Moreover, CelMytB could degrade xylan. From the zymogram results, we speculated that the catalytic domain of CelMytB had high activity even without the cellulose binding module. The presence of some detergents stimulated the cellulase activity of CelMytB.     

Apparent cellulase activity of purified xylanase is due to contamination of assay substrate with xylan

Summary Purified xylanase A ofTrichoderma longibrachiatum was active on one of two carboxymethyl cellulose (CMC) preparations used as cellulase assay substrates. The pattern of enzyme activity, and analysis of the substrate by acid hydrolysis and thin-layer chromatography (TLC) suggested that the enzyme had acted on xylan present in the CMC.     

Application of cellulase and hemicellulase to pure xylan, pure cellulose, and switchgrass solids from leading pretreatments

Accellerase 1000 cellulase, Spezyme CP cellulase, β-glucosidase, Multifect xylanase, and beta-xylosidase were evaluated for hydrolysis of pure cellulose, pure xylan, and switchgrass solids from leading pretreatments of dilute sulfuric acid, sulfur dioxide, liquid hot water, lime, soaking in aqueous ammonia, and ammonia fiber expansion. Distinctive sugar release patterns were observed from Avicel, phosphoric acid swollen cellulose (PASC), xylan, and pretreated switchgrass solids, with accumulation of significant amounts of xylooligomers during xylan hydrolysis. The strong inhibition of cellulose hydrolysis by xylooligomers could be partially attributed to the negative impact of xylooligomers on cellulase adsorption. The digestibility of pretreated switchgrass varied with pretreatment but could not be consistently correlated to xylan, lignin, or acetyl removal. Initial hydrolysis rates did correlate well with cellulase adsorption capacities for all pretreatments except lime, but more investigation is needed to relate this behavior to physical and compositional properties of pretreated switchgrass.