Expression of the cloned xylanases from an alkalophilic,thermophilic Bacillus in Bacillus subtilis

A recombinant plasmid construct, pLPX6.5, harbouring a 6.5 kb Hind III fragment of genomic DNA, from an alkalophilic, thermophilic Bacillus NCIM 59 and coding for xylanase activity, was electroporatically transformed into Bacillus subtilis MI 111. The expression of the recombinant xylanases was confirmed by cross-reactivity with antibodies raised against purified xylanase II (M _r 15,800) from NCIM 59. However, as there were different xylan hydrolysis products from NCIM 59 and the host B. subtilis, the two xylanases appear to have different modes of action. Xylanase expression in the transformants was 6-fold higher than in the host. There was no significant enhancement in the expression of recombinant xylanases by adding xylan to the growth medium.The authors are with the Division of Biochemical Sciences, National Chemical Laboratory, Pune-411008, India     

Production and properties of xylanases from thermophilic actinomycetes

30 strains of xylanolytic thermophilic actinomycetes were isolated from composted grass and cattle manure and identified as members of the generaThermomonospora, Saccharomonospora, Microbispora, Streptomyces andActinomadura. Screening of these strains for extracellular xylanase indicated that strains ofSaccharomonospora andMicrobispora generally were poor xylanase producers (0.5–1.5 U/ml) whereas relatively high activities were observed in cultures ofStreptomyces andActionomadura (4–12 U/ml).A preliminary characterization of the enzymes of strains of the latter genera suggested that xylanases of all the strains ofActinomadura exhibited higher thermostabilities than those ofStreptomyces. To evaluate the potential of thermophilicActinomadura for industrial applications, xylanases of three strains were studied in more detail. The highest activity levels for xylanases were observed in cultures grown on xylan and wheat bran. The optimal pH and temperature for xylanase activities ranged from 6.0 to 7.0 and 70 to 80°C. The enzymes exhibited considerable thermostability at their optimum temperature. The half-lives at 75°C were in the range from 6.5 to 17h. Hydrolysis of xylan by extracellular xylanases yielded xylobiose, xylose and arabinose as principal products. Estimated by the amount of reducing sugars liberated the degree of hydrolysis was 55 to 65%. Complete utilization of xylan is presumably achieved by -xylosidase activities which could be shown to be largely cell-associated in the 3Actinomadura strains.     

The role of two Trichoderma reesei xylanases in the bleaching of pine kraft pulp

Summary The two major xylanases of Trichoderma reesei with different pI values and pH optima were compared for increasing the bleachability of pine kraft pulp. The efficiencies of the two enzymes acting on pulp substrate were very similar in hydrolysis yield, extraction kappa number or final brightness value. Only slight synergism between the two enzymes was observed in both hydrolysis and bleaching tests. The pH optimum of the pI 5.5 xylanase was similar in pulp treatment and in the hydrolysis of isolated substrates, and the bleaching result also correlated well with the hydrolysis of pulp xylan. By contrast, the pI 9.0 xylanase acted differently on pulp than on isolated xylans at different pH values and the pH optimum on pulp was increased. The bleachability of pulp by the pI 9.0 xylanase was improved more than expected at pH 7.0, although the hydrolysis of pulp xylan was substantially decreased. A similar phenomenon was also observed when the hydrolysis was performed in water instead of buffer. It thus appears that the degree of hydrolysis needed to obtain improved bleachability with pI 9.0 xylanase can be minimized by proper adjustment of the hydrolysis conditions. Correspondence to: J. Buchert     

Family-10 and Family-11 xylanases differ in their capacity to enhance the bleachability of hardwood and softwood paper pulps

Enzyme-aided bleaching of softwood and hardwood kraft pulps by glycosyl hydrolase family-10 and -11 xylanases and a family-26 mannanase was investigated. The ability to release reducing sugar from pulp xylan and to enhance bleachability is not a characteristic shared by all xylanases. Of the six enzymes tested, two xylanases belonging to family 11 were most effective at increasing bleachability and improving final paper brightness. None of the enzymes had a deleterious effect on pulp fibre integrity. The efficiency of individual xylanases as bleach enhancers was not dependent on the source microorganism, and could not be predicted solely on the basis of the quantity or nature of products released from pulp xylan. Cooperative interactions between xylanase/xylanase and xylanase/mannanase combinations, during the pretreatment of softwood and hardwood pulps, were investigated. Synergistic effects on reducing-sugar release and kappa number reduction were elicited by a combination of two family-10 xylanases. Pretreatment of kraft pulp with mannanase A from Pseudomonas fluorescens subsp. cellulosa and any one of a number of xylanases resulted in increased release of reducing sugar and a larger reduction in kappa number than obtained with the xylanases alone, confirming the beneficial effects of family-26 mannanases on enzyme-aided bleaching of paper pulp. Received: 6 January 1997 / Received revision: 10 April 1997 / Accepted: 19 April 1997     

A comparison of two xylanases from the thermophilic fungi Thielavia terrestris and Thermoascus crustaceus

Two thermophilic xylanases (xylanase II from Thielavia terrestris 255B and the 32-kDa xylanase from Thermoascus crustaceus 235E) were studied to determine if they had different and complementary modes of action when they hydrolysed various types of xylans. Partial amino acid sequencing showed that these two enzymes belonged to different families of -1,4-glycanases. Xylanase II achieved faster solubilization of insoluble xylan whereas the 32-kDa xylanase was more effective in producing xylose and short xylooligomers. An assessment of the combined hydrolytic action of the two xylanases did not reveal any co-operative action. The sugars released when the two thermophilic xylanases were used together were almost identical to those released when the 32-kDa xylanase acted alone. The two xylanases were able to remove about 12% of the xylan remaining in an aspen kraft pulp. This indicated that either one of these thermophilic enzymes may be useful for enhancing the bleaching of kraft pulps. Correspondence to: J. N. Saddler     

Relationships between activities of xylanases and xylan structures

Structures of five water-soluble xylans have been determined. Four purified xylanase enzymes have been studied for the hydrolysis of the xylans. Different xylanases have different activities against various xylan structures. The key factors that influence the rate of xylan hydrolysis are chain length and degree of substitution. Two family 11 xylanases, Orpinomyces pc2 xylanase and Trichoderma longibrachiatum xylanase, can rapidly hydrolyze xylans that have a chain length greater than 8 xylose residues, and their hydrolytic rates are not sensitive to substituents on the xylan backbone. A family 11 xylanase from Aureobasidium pullulans is most effective on xylans that have a long chain (greater than 19 xylose residues), and also is effective against substituent groups. Although Thermatoga maritima xylanase is also more active on a long xylan chain (greater than 19 xylose residues), its hydrolytic rate is greatly reduced by substituents on xylan backbones.     

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.     

Comparison of the synergistic action of two thermostable xylanases from GH families 10 and 11 with thermostable cellulases in lignocellulose hydrolysis

Recombinant xylanase preparations from Nonomuraea flexuosa (Nf Xyn, GH11) and Thermoascus aurantiacus (Ta Xyn, GH10) were evaluated for their abilities to hydrolyze hydrothermally pretreated wheat straw. The GH family 10 enzyme Ta Xyn was clearly more efficient in solubilizing xylan from pretreated wheat straw. Improvement of the hydrolysis of hydrothermally pretreated wheat straw by addition of the thermostable xylanase preparations to thermostable cellulases was evaluated. Clear synergistic enhancement of hydrolysis of cellulose was observed when cellulases were supplemented even with a low amount of pure xylanases. Xylobiose was the main hydrolysis product from xylan. It was found that the hydrolysis of cellulose increased nearly linearly with xylan removal during the enzymatic hydrolysis. The results also showed that the xylanase preparation from T. aurantiacus, belonging to GH family 10 always showed better hydrolytic capacity of solubilizing xylan and acting synergistically with thermostable cellulases in the hydrolysis of hydrothermally pretreated wheat straw.     

Purification and characterization of xylanases from<Emphasis Type="Italic">Aspergillus giganteus</Emphasis>

A strain of Aspergillus giganteus cultivated in a medium with xylan produced two xylanases (xylanase I and II) which were purified to homogeneity. Their molar mass, estimated by SDS-PAGE, were 21 and 24 kDa, respectively. Both enzymes are glycoproteins with 50 degrees C temperature optimum; optimum pH was 6.0-6.5 for xylanase I and 6.0 for xylanase II. At 50 degrees C xylanase I exhibited higher thermostability than xylanase II. Hg2+, Cu2+ and SDS were strong inhibitors, 1,4-dithiothreitol stimulated the reaction of both enzymes. Both xylanases are xylan-specific; kinetic parameters indicated higher efficiency in the hydrolysis of oat spelts xylan. In hydrolysis of this substrate, xylotriose, xylotetraose and larger xylooligosaccharides were released and hence the enzymes were classified as endoxylanases.     

The identification,purification, and characterization of STXF10 expressed in <Emphasis Type="Italic">Streptomyces thermonitrificans</Emphasis> NTU-88

Multiple xylanolytic enzymes of Streptomyces thermonitrificans NTU-88 were induced by oat-spelt xylan and separated by two-dimensional polyacrylamide and zymogram gels. Nineteen clear spots differed in pI and molecular weight values were found on the zymogram, and only spot one was seen on the corresponding silver-stained gel. These results revealed that multiple xylanases were secreted when S. thermonitrificans NTU-88 was induced and the spot (STXF10), identified as being a glycosyl hydrolase family 10 xylanase, was the predominant one among xylanases. STXF10 showed a tolerance for high temperatures and broad pH ranges and high affinity and hydrolysis efficiency for xylans. Furthermore, it also featured the minor ability to degrade different lignocellulosic substrates. Although S. thermonitrificans NTU-88 possesses multiple xylanases, our results suggest that the major form of xylanase might be selectively and specifically induced depending on the type of substrate to which the microorganism is exposed.     

Degradation and Utilization of Xylans by the Rumen AnaerobePrevotella bryantii(formerlyP. ruminicolasubsp.brevis) B14

Freshly harvested whole cells from cultures ofP. bryantiiB₁4 grown with oat spelt xylan (OSX) as an energy source showed less than 25% of the enzyme activity against OSX, and less than 15% of the activity against birchwood xylan (BWX) and carboxymethylcellulose, that was detectable in sonicated cell preparations. This indicates that much of this hydrolytic activity is either periplasmic, membrane-associated or intracellular and may be concerned with the processing of transported oligosaccharides.P. bryantiiB₁4 cultures were able to utilise up to 45% and 51% of the total pentose present in OSX and BWX, respectively, after 24 h, but could utilize 84% of a water-soluble fraction of BWX. Analysis of the xylan left undegraded after incubation withP. bryantiishowed that while xylose and arabinose were removed to a similar extent, uronic acids were utilized to a greater extent than xylose. Predigestion of xylans with two cloned xylanases from the cellulolytic rumen anaerobeRuminococcus flavefaciensgave little increase in overall pentose utilization suggesting that externalP. bryantiixylanases are as effective as the clonedR. flavefaciensenzymes in releasing products that can be utilised byP. bryantiicells. The xylanase system ofP. bryantiiis able to efficiently utilise not only xylo-oligosaccharides but also larger water-soluble xylan fragments.     

Xylanase production by Trichoderma harzianum E58

Summary Growth of Trichoderma harzianum E58 on hemicellulose-rich media, both in batch and fermentor cultures, resulted in independent profiles for the production of xylanase and endoglucanase enzymes. Dramatic differences in the ratio of xylanase to endoglucanase activities were observed among cultures grown on cellulose-rich Solka Floc and xylan. These results indicated that the induction of xylanases and cellulases was likely to be under separate regulatory control. The specific activity and amount of xylanases produced were found to be dependent on the concentration of xylan in the growth media. Growth on oat spelts xylan or the hemicellulose-rich, water-soluble fraction from steam-treated aspenwood (SEA-WS) greatly enhanced the production of xylanases and xylosidase in the culture filtrates. Constitutive levels of xylanase and endoglucanase enzymes were detected during growth of the fungus on glucose.Offprint requests to: D. J. Senior     

Xylanase Produced by Alkalophilic Bacillus No. C-59-2

Bacillus No. C–59–2 isolated from soil produced a xylanase in alkaline media. The characteristic point of this bacteria was especially good growth in alkaline media, and no growth was observed in neutral media such as nutrient broth. The xylanase of this bacteria was purified by CM-celluIose, hydroxyl apatite and Sephadex G–75 columns. The enzyme was most active at pH 5.5~9 which was much broader and higher than those of other xylanases. The sedimentation constant was about 3.5 S and isoelectric point was pH 6.3. The enzyme was most stable at pH 7 and calcium ion was effective to stabilize the enzyme. The enzyme activity was inhibited by Hg²⁺, Ag²⁺ and Cd^{2 +} Maximum hydrolysis rate of xylan by the enzyme was about 40%. The enzyme split xylan and yielded xylobiose and higher oligosaccharides. Therefore, this enzyme is considered to be a type of endo-xylanase.     

Purification and characterization of two different xylanases from the thermophilic actinomycete Microtetraspora flexuosa SIIX

Two endoxylanases were isolated from the xylanolytic enzyme system of the thermophilic actinomycete Microtetraspora flexuosa SIIX, and purified by ammonium sulfate fractionation, DEAE-Sepharose chromatography, gel filtration on Sephacryl S 200 and fast protein liquid chromatography on Q-Sepharose. The molecular masses of xylanase I and II were 26.3 and 16.8 kDa, and isoelectric points were 8.4 and 9.45, respectively. optimal enzyme activities were obtained at 80° C and pH 6.0. The thermostability of both xylanases was greatly diminished during purification but could be restored by preincubation of the purified enzymes in the presence of xylan. The half-lives at 80° C were approximately 25 min. The kinetic constants of xylanases I and II determined with Remazol-brilliant-blue xylan were V_max of 1537 and 353 mol·min^-1·mg protein^-1 and K _m values of 2.44 and 1.07 mg·ml^-1, respectively. Purified xylanases utilized xylan as well as small oligosaccharides such as xylotriose as substrate. They did not exhibit xylobiase or debranching activities. The predominant products of arabinoxylan hydrolysis were xylobiose and xylotriose, the latter being hydrolysed to xylobiose and xylose upon further incubation. In addition, fragments containing arabinose side chains accumulated. The xylanases did not act on crystalline or amorphous cellulose indicating a possible application in biobleaching processes.     

Functional analysis of glycoside hydrolase family 8 xylanases shows narrow but distinct substrate specificities and biotechnological potential

The potential of glycoside hydrolase family (GH) 8 xylanases in biotechnological applications is virtually unexplored. Therefore, the substrate preference and hydrolysis product profiles of two GH8 xylanases were evaluated to investigate their activities and substrate specificities. A GH8 xylanase from an uncultured bacterium (rXyn8) shows endo action but very selectively releases xylotriose from its substrates. It has a higher activity than the Pseudoalteromonas haloplanktis GH8 endo-xylanase (PhXyl) on xylononaose and smaller xylo-oligosaccharides. PhXyl preferably degrades xylan substrates with a high degree of polymerization. It is sterically more hindered by arabinose substituents than rXyn8, producing larger end hydrolysis products. The specificities of rXyn8 and PhXyl differ completely from these of the previously described GH8 xylanases from Bifidobacterium adolescentis (BaRexA) and Bacillus halodurans (BhRex). As reducing-end xylose-releasing exo-oligoxylanases, they selectively release xylose from the reducing end of small xylo-oligosaccharides. The findings of this study show that GH8 xylanases have a narrow substrate specificity, but also one that strongly varies between family members and is distinct from that of GH10 and GH11 xylanases. Structural comparison of rXyn8, PhXyl, BaRexA, and BhRex showed that subtle amino acid changes in the glycon as well as the aglycon subsites probably form the basis of the observed differences between GH8 xylanases. GH8 xylanases, therefore, are an interesting group of enzymes, with potential towards engineering and applications.     

Xylanases of thermophilic bacteria from Icelandic hot springs

Thermophilic, aerobic bacteria isolated from Icelandic hot springs were screened for xylanase activity. Of 97 strains tested, 14 were found to be xylanase positive. Xylanase activities up to 12 nkat/ml were produced by these strains in shake flasks on xylan medium. The xylanases of the two strains producing the highest activities (ITI 36 and ITI 283) were similar with respect to temperature and pH optima (80°C and pH 8.0). Xylanase production of strain ITI 36 was found to be induced by xylan and xylose. Xylanase activity of 24 nkat/ml was obtained with this strain in a laboratory-scale-fermentor cultivation on xylose medium. -Xylosidase activity was also detected in the culture filtrate. The thermal half-life of ITI 36 xylanase was 24 h at 70°C. The highest production of sugars from hydrolysis of beech xylan was obtained at 70°C, although xylan depolymerization was detected even up to 90°C. Correspondence to: M. Rättö     

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.     

Production and Properties of Extracellular Endoxylanase from Neurospora crassa

Neurospora crassa 870 produced 14 and 0.025 U of extracellular xylanase (1,4-beta-d-xylan xylanohydrolase; EC 3.2.1.8) and beta-xylosidase (1,4-beta-xylan xylohydrolase; EC 3.2.1.37) per ml, respectively, in 4 days when commercial xylan was used as a carbon source. The effects of pH and carbon sources on xylanase production by N. crassa are discussed. Two xylanases (I and II) were purified and had pI values of 4.8 and 4.5 and molecular weights of 33,000 and 30,000. The maximum degree of hydrolysis of xylan by the extracellular culture broth was 66% in 4 h. The end products of xylan hydrolysis by xylanase I and II showed the presence of xylose, xylobiose, xylotriose, xylotetraose, xylopentose, and arabinose, indicating that they are endoxylanases capable of hydrolyzing 1,3-alpha-l-arabinofuranosyl branch points. Both xylanases showed activity toward carboxymethyl cellulose but no activity toward para-nitrophenyl-beta-d-xyloside or laminarin. Xylanase I showed appreciable activity toward para-nitrophenyl-beta-d-glucoside, whereas xylanase II was inactive.     

Purification and characterization of two sugarcane bagasse-absorbable thermophilic xylanases from the mesophilic <Emphasis Type="Italic">Cellulomonas flavigena</Emphasis>

We report the purification and characterization of two thermophilic xylanases from the mesophilic bacteria Cellulomonas flavigena grown on sugarcane bagasse (SCB) as the only carbon source. Extracellular xylanase activity produced by C. flavigena was found both free in the culture supernatant and associated with residual SCB. To identify some of the molecules responsible for the xylanase activity in the substrate-bound fraction, residual SCB was treated with 3 M guanidine hydrochloride and then with 6 M urea. Further analysis of the eluted material led to the identification of two xylanases Xyl36 (36 kDa) and Xyl53 (53 kDa). The pI for Xyl36 was 5.0, while the pI for Xyl53 was 4.5. Xyl36 had a K _m value of 1.95 mg/ml, while Xyl53 had a K _m value of 0.78 mg/ml. In addition to SCB, Xyl36 and Xyl53 were also able to bind to insoluble oat spelt xylan and Avicel, as shown by substrate-binding assays. Xyl36 and Xyl53 showed optimal activity at pH 6.5, and at optimal temperature 65 and 55°C, respectively. Xyl36 and Xyl53 retained 24 and 35%, respectively, of their original activity after 8 h of incubation at their optimal temperature. As far as we know, this is the first study on the thermostability properties of purified xylanases from microorganisms belonging to the genus Cellulomonas.     

Influence of xylan on the enzymatic hydrolysis of steam‐pretreated corn stover and hybrid poplar

The focus of this study was to alter the xylan content of corn stover and poplar using SO₂‐catalyzed steam pretreatment to determine the effect on subsequent hydrolysis by commercial cellulase preparations supplemented with or without xylanases. Steam pretreated solids with xylan contents ranging from ～1 to 19% (w/w) were produced. Higher xylan contents and improved hemicellulose recoveries were obtained with solids pretreated at lower severities or without SO₂‐addition prior to pretreatment. The pretreated solids with low xylan content (<4% (w/w)) were characterized by fast and complete cellulose to glucose conversion when utilizing cellulases. Commercial cellulases required xylanase supplementation for effective hydrolysis of pretreated substrates containing higher amounts of xylan. It was apparent that the xylan content influenced both the enzyme requirements for hydrolysis and the recovery of sugars during the pretreatment process. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009