An acetyl esterase of Trichoderma reesei and its role in the hydrolysis of acetyl xylans

Summary An acetyl esterase was purified from Trichoderma reesei by cation and anion exchange chromatography. The enzyme had a molecular weight of 45 000 as determined by SDS-electrophoresis, or 67 000 as determined by gel filtration. In chromatofocusing the enzyme was shown to consist of two isoenzymes with isoelectric points of 6.8 and 6.0. The enzyme showed activity towards naphthyl acetate, triacetin and glucose-and xylose acetates. However, it liberated acetic acid from acetylated xylo-oligomers only to a small extent. The liberation of acetic acid from the oligomeric substrate was enhanced by addition of endoxylanase and -xylosidase.     

Deacetylation of xylans by acetyl esterases of Trichoderma reesei

Summary Two previously purified esterases of Trichoderma reesei were used to study the deacetylation of polymeric, oligomeric and dimeric acetylated xylan fragments. For the first time nearly complete enzymatic deacetylation of polymeric xylan with purified acetyl xylan esterase was demonstrated, resulting in precipitation of the remaining polymer structure. The esterases had very different substrate specifities, one having a preference for high molecular weight substrates and the other showing high activity only towards acetyl xylobiose. The latter enzyme was also regioselective, cleaving off the acetyl substituent only from the C-3 position of the xylopyranose ring. The highest xylose yield from acetylated xylan was obtained by the synergistic action of xylanase, \-xylosidase and acetyl xylan esterase. Offprint requests to: M. Sundberg     

Enzymatic hydrolosis of isolated and fibre-bound galactoglucomannans from pine-wood and pine kraft pulp

Fibre-bound and isolated galactoglumanans from pine-wood and pine kraft pulp were hydrolysed with purified mannanases from Trichoderma reesei and Bacillus subtilis. The isolated galactoglucomannans from both wood and pulp could be hydrolysed fairly extensively with both enzymes. In addition to mixed oligomers, the fungal mannase produced mannobiose as the main hydrolysis product whereas the bacterial mannanase produced mannobiose, mannotriose and mannotetraose. Both enzymes hydrolysed the native galactoglucomannan in finely ground pinewood, whereas galactoglucomannan in pine kraft pulp was only hydrolysed by the T. ressei mannanase. Thus, mannanases exhibit different specificities on fibre-bound, modified substrates. In spite of the high enzyme loading, the degree of hydrolysis of fibre-bound substrates did not exceed 10% of the theoretical, probably due to poor accessibility of the substrates. Correspondence to: M. Rättö     

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-β-

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-xylopyranoside was deacetylated at positions 2 and 3, yielding methyl 4-O-acetyl-β-

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-xylopyranoside in almost 90% yield. Methyl 2,3-di-O-acetyl β-

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-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 β-1,4-linked xylans, the enzyme deacetylates monoacetylated xylopyranosyl residues more readily than di-O-acetylated residues. The T. reesei AcXE attacked acetylated methyl β-

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-glucopyranosides and β-

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-mannopyranosides in a manner similar to the xylopyranosides.     

Trichoderma reesei CE16 acetyl esterase and its role in enzymatic degradation of acetylated hemicellulose

Background

Trichoderma reesei CE16 acetyl esterase (AcE) is a component of the plant cell wall degrading system of the fungus. The enzyme behaves as an exo-acting deacetylase removing acetyl groups from non-reducing end sugar residues.

Methods

In this work we demonstrate this exo-deacetylating activity on natural acetylated xylooligosaccharides using MALDI ToF MS.

Results

The combined action of GH10 xylanase and acetylxylan esterases (AcXEs) leads to formation of neutral and acidic xylooligosaccharides with a few resistant acetyl groups mainly at their non-reducing ends. We show here that these acetyl groups serve as targets for TrCE16 AcE. The most prominent target is the 3-O-acetyl group at the non-reducing terminal Xylp residues of linear neutral xylooligosaccharides or on aldouronic acids carrying MeGlcA at the non-reducing terminus. Deacetylation of the non-reducing end sugar may involve migration of acetyl groups to position 4, which also serves as substrate of the TrCE16 esterase.

Conclusion

Concerted action of CtGH10 xylanase, an AcXE and TrCE16 AcE resulted in close to complete deacetylation of neutral xylooligosaccharides, whereas substitution with MeGlcA prevents removal of acetyl groups from only a small fraction of the aldouronic acids. Experiments with diacetyl derivatives of methyl β-d-xylopyranoside confirmed that the best substrate of TrCE16 AcE is 3-O-acetylated Xylp residue followed by 4-O-acetylated Xylp residue with a free vicinal hydroxyl group.

General significance

This study shows that CE16 acetyl esterases are crucial enzymes to achieve complete deacetylation and, consequently, complete the saccharification of acetylated xylans by xylanases, which is an important task of current biotechnology.     

Localization of Acetyl Groups in the Macromolecule of Glucomannan Obtained from Roots of Eremurus zangezuricus

Water-soluble glucomannan from roots of Eremurus zangezuricus Mikheev was studied. The polysaccharide contains D-glucose, D-mannose, and acetyl groups in the molecular ratio of 1 : 2.8 : 0.38. ¹³C NMR studies showed that the polysaccharide under study is a linear, partly acetylated 1,4--D-glucomannan. The acetyl groups are attached to the C2 and C3 of mannopyranose units. The polymer contains, on average, one acetyl group per seven mannose units. The glucomannan of E. zangezuricus has the following parameters: []_D = –37.5°, [] = 3.73 dl/g, and Mw = 151 kDa.     

Characterization of a Cellobiohydrolase (MoCel6A) Produced by Magnaporthe oryzae

Three GH-6 family cellobiohydrolases are expected in the genome of Magnaporthe grisea based on the complete genome sequence. Here, we demonstrate the properties, kinetics, and substrate specificities of a Magnaporthe oryzae GH-6 family cellobiohydrolase (MoCel6A). In addition, the effect of cellobiose on MoCel6A activity was also investigated. MoCel6A contiguously fused to a histidine tag was overexpressed in M. oryzae and purified by affinity chromatography. MoCel6A showed higher hydrolytic activities on phosphoric acid-swollen cellulose (PSC), β-glucan, and cellooligosaccharide derivatives than on cellulose, of which the best substrates were cellooligosaccharides. A tandemly aligned cellulose binding domain (CBD) at the N terminus caused increased activity on cellulose and PSC, whereas deletion of the CBD (catalytic domain only) showed decreased activity on cellulose. MoCel6A hydrolysis of cellooligosaccharides and sulforhodamine-conjugated cellooligosaccharides was not inhibited by exogenously adding cellobiose up to 438 mM, which, rather, enhanced activity, whereas a GH-7 family cellobiohydrolase from M. oryzae (MoCel7A) was severely inhibited by more than 29 mM cellobiose. Furthermore, we assessed the effects of cellobiose on hydrolytic activities using MoCel6A and Trichoderma reesei cellobiohydrolase (TrCel6A), which were prepared in Aspergillus oryzae. MoCel6A showed increased hydrolysis of cellopentaose used as a substrate in the presence of 292 mM cellobiose at pH 4.5 and pH 6.0, and enhanced activity disappeared at pH 9.0. In contrast, TrCel6A exhibited slightly increased hydrolysis at pH 4.5, and hydrolysis was severely inhibited at pH 9.0. These results suggest that enhancement or inhibition of hydrolytic activities by cellobiose is dependent on the reaction mixture pH.Cellulose, composed of β-1,4-linked glucosyl units, is the most abundant naturally produced biopolymer on earth and can be utilized as a sustainable and renewable energy resource in place of fossil fuel. Establishing conditions for the efficient degradation of cellulose will contribute to the enhanced use of bioethanol, a biobased alternative to gasoline, which will increase biomass recycling and reduce carbon dioxide emissions (21, 30). Hence, efficient degradation of cellulose is an issue of great importance today.Bacteria and fungi produce cellulases that catalyze the hydrolysis of β-1,4-glycosidic bonds and are involved in the degradation of cellulose. Cellulases are divided into three major types according to their substrate specificities and the mode of hydrolysis: endoglucanases (EC 3.2.1.4), cellobiohydrolases (EC 3.2.1.91), and β-glucosidases (EC 3.2.1.21). The most efficient hydrolysis of cellulose is thought to result from the combined synergistic actions of cellulases, whereby the enzymatic activity of an enzyme mixture is substantially higher than the sum of the activities of the individual enzymes. Several types of synergy have been described as the cooperative actions of endo- and exo-acting enzymes (20, 25, 32, 33, 45). Such cellulose-degrading enzymes are routinely used in the manufacture of beverages and industrial products, e.g., beer and wine, animal feed, paper, textiles, laundry detergents, and food ingredients (5). Hence, reducing cellulase manufacturing costs by increasing the productivity of cellulases with high specific activities through biotechnological modification is a desired research goal.Fungal cellobiohydrolases belong to glycosyl hydrolase families 6 and 7 (GH-6 and -7) and act most efficiently on highly ordered crystalline cellulose, hydrolyzing from either the reducing or the nonreducing terminus to liberate predominantly cellobiose (C2) with a minor amount of cellotriose (C3) (6, 39, 40). Also, Trichoderma reesei Cel6A can hydrolyze 1,3-1,4-β-glucan (1, 18), but it is unclear whether in vivo it is hydrolysis of 1,3-1,4-β-glucan that occurs mainly or hydrolysis of cellulose derivatives. The resulting accumulation of cellobiose inhibits the activity of cellobiohydrolase (13, 15, 28, 31, 36, 37, 44). Some microorganisms possess cellulosomes, multienzyme complexes that contribute to the efficient degradation of cellulose. Cellobiohydrolase is a documented component of cellulosomes in Clostridium thermocellum (2, 31).The three-dimensional (3D) structures of two GH-6 family members have been elucidated, including the cellobiohydrolase of T. reesei and that of Humicola insolens in complex with glucose, cellooligosaccharide, and a nonhydrolyzable substrate analogue (35, 41-43). The proposed structures have identified the significant amino acids associated with the catalytic core domain, where the catalytic site is buried inside a tunnel-shaped cavity and an enzyme-cellooligosaccharide hydrogen bond network. The structure suggests that the mode of action proceeds in a processive manner as cellobiohydrolase progresses along the cellulose chain (7, 19, 34, 40).The ascomycete fungus Magnaporthe grisea is the pathogen that causes rice blast, the most devastating fungal disease of rice. Since the complete genome sequence of M. grisea has been published (10), mining the database for candidate genes involved in pathogen-plant interactions, cell wall degradation, etc., is quite feasible. The cell wall-degrading enzymes of the genus Magnaporthe that are involved in the infection process have been of particular interest (22-24). Based on the complete genome sequence, M. grisea has three putative GH-6 family cellobiohydrolases and four GH-7 family cellobiohydrolases. Using primers designed from the database of M. grisea cellobiohydrolases, we cloned putative GH-6 and GH-7 family cellobiohydrolases, designated MoCel6A and MoCel7A, respectively, from Magnaporthe oryzae by PCR. The cloned MoCel6A and MoCel7A from M. oryzae were completely identical to those of M. grisea. In this paper, we demonstrate the properties of MoCel6A prepared by homologous overexpression in M. oryzae and examine the effects of cellobiose on the hydrolytic activity of MoCel6A. Furthermore, the effects of cellobiose on the activities of both MoCel6A and a T. reesei GH family 6 cellobiohydrolase (TrCel6A, formerly referred to as CBH II), which were overexpressed in Aspergillus oryzae, were also examined.     

Studies on Mannan in Wood Pulp

X-Ray analysis was carried out on a purified glucomannan specimen isolated from Aka-matsu wood (Pinus densiflora Sieb. et Zucc.). An X-ray diffraction diagram of a pure glucomannan showed a distinct crystalline pattern of undegraded glucomannan molecule having two diffraction points of 21° and 23° respectively but arabinoglucuronoxylan had no crystalline structure. An aqueous solution of purified glucomannan yielded characteristic skin-band when the solubility of the glucomannan was reduced. The skin-band indicated an optical anisotropic property under polarization microscope so that the skin-band was thought to consist of the ordered glucomannan molecules.     

An overview of mannan structure and mannan-degrading enzyme systems

Hemicellulose is a complex group of heterogeneous polymers and represents one of the major sources of renewable organic matter. Mannan is one of the major constituent groups of hemicellulose in the wall of higher plants. It comprises linear or branched polymers derived from sugars such as d-mannose, d-galactose, and d-glucose. The principal component of softwood hemicellulose is glucomannan. Structural studies revealed that the galactosyl side chain hydrogen interacts to the mannan backbone intramolecularly and provides structural stability. Differences in the distribution of d-galactosyl units along the mannan structure are found in galactomannans from different sources. Acetyl groups were identified and distributed irregularly in glucomannan. Some of the mannosyl units of galactoglucomannan are partially substituted by O-acetyl groups. Some unusual structures are found in the mannan family from seaweed, showing a complex system of sulfated structure. Endohydrolases and exohydrolases are involved in the breakdown of the mannan backbone to oligosaccharides or fermentable sugars. The main-chain mannan-degrading enzymes include β-mannanase, β-glucosidase, and β-mannosidase. Additional enzymes such as acetyl mannan esterase and α-galactosidase are required to remove side-chain substituents that are attached at various points on mannan, creating more sites for subsequent enzymatic hydrolysis. Mannan-degrading enzymes have found applications in the pharmaceutical, food, feed, and pulp and paper industries. This review reports the structure of mannans and some biochemical properties and applications of mannan-degrading enzymes.     

Purification and Characterization of Chitosanase and Exo-β-D-Glucosaminidase from a Koji Mold,Aspergillus oryzae IAM2660

Chitosan-degrading activity was detected in the culture fluid of Aspergillus oryzae, A. sojae, and A. flavus among various fungal strains belonging to the genus Aspergillus. One of the strong producers, A. oryzae IAM2660 had a higher level of chitosanolytic activity when N-acetylglucosamine (GlcNAc) was used as a carbon source. Two chitosanolytic enzymes, 40 kDa and 135 kDa in molecular masses, were purified from the culture fluid of A. oryzae IAM2660. Viscosimetric assay and an analysis of reaction products by thin-layer chromatography clearly indicated the endo- and exo-type cleavage manner for the 40-kDa and 135-kDa enzymes, respectively. The 40-kDa enzyme, designated chitosanase, catalyzed a hydrolysis of glucosamine (GlcN) oligomers larger than pentamer, glycol chitosan, and chitosan with a low degree of acetylation (0-30%). The 135-kDa enzyme, named exo-β-D-glucosaminidase, released a single GlcN residue from the GlcN oligomers and chitosan, but did not release GlcNAc residues from either GlcNAc oligomer or colloidal chitin.     

Purification and Characterization of an Esterase Involved in Poly(vinyl alcohol) Degradation by Pseudomonas vesicularis PD

An esterase catalyzing the hydrolysis of acetyl ester moieties in poly(vinyl alcohol) was purified 400-fold to electrophoretic homogeneity from the cytoplasmic fraction of Pseudomonas vesicularis PD, which was capable of assimilating poly(vinyl alcohol) as the sole carbon and energy source. The purified enzyme was a homodimeric protein with a molecular mass of 80 kDa and the isoelectric point was 6.8. The pH and temperature optima of the enzyme were 8.0 and 45°C. The enzyme catalyzed the hydrolysis of side chains of poly(vinyl alcohol), short-chain p-nitrophenyl esters, 2-naphthyl acetate, and phenyl acetate, and was slightly active toward aliphatic esters. The enzyme was also active toward the enzymatic degradation products, acetoxy hydroxy fatty acids, of poly(vinyl alcohol). The K _m and V _max of poly(vinyl alcohol) (degree of polymerization, 500; saponification degree, 86.5-89.0 mol%) and p-nitrophenyl acetate were 0.381% (10.6 mM as acetyl content in the polymer) and 2.56 μM, and 6.52 and 12.6 μmol/min/mg, respectively. The enzyme was strongly inhibited by phenylmethylsulfonyl fluoride and diisopropyl fluorophosphate at a concentration of 5 mM, which indicated that the enzyme was a serine esterase. The pathway for the metabolism of poly(vinyl alcohol) is also discussed.     

新型甘露聚糖酶-乙酰酯酶双功能酶的功能和结构域协同研究

[目的] 分析鉴定高效木质纤维素降解菌群EMSD5来源的新型甘露聚糖酶-乙酰酯酶双功能酶44884,解析催化域间的协同关系,以及碳水化合物结合模块（CBM）对催化域特性的影响,拓展对该类双功能酶的认识,为甘露聚糖酶的升级改造和应用提供依据。[方法] 通过大肠杆菌异源表达甘露聚糖酶-乙酰酯酶双功能酶44884,并构建截短和定点突变的突变体,利用TLC和DNS法比较野生型和突变体的酶学性质。[结果] 成功对44884全长和突变蛋白进行克隆表达,并发现44884中2个催化域能够彼此促进各自产物的释放,而且以双功能酶形式存在时,这种促进效果更为明显。44884中的2个CBM65均有甘露聚糖和结晶纤维素结合活性,且CBM65的存在并不改变甘露聚糖酶和乙酰酯酶的最适反应条件和水解模式。虽然CBM65显著降低了2个催化域的热稳定性,但水解天然底物时,2个CBM65对各自临近催化域的水解具有明显的促进效果。[结论] 本研究首次发现并探究了新型甘露聚糖酶和乙酰酯酶形成的双功能酶44884的功能,解析了催化域之间高效的协同效应,以及新型甘露聚糖结合模块CBM65对双功能酶水解的促进作用。     

Overproduction of an acetylxylan esterase from the extreme thermophile “Caldocellum saccharolyticum” in Escherichia coli

Summary The xynC gene coding for an acetylxylan esterase from the extreme thermophile Caldocellum saccharolyticum was overexpressed in Escherichia coli strain RR28 by cloning the gene downstream from the lacZ promoter region of pUC18 (pNZ1447) or downstream from the temperature-inducible p _r p _l promoters of pJLA602 (pNZ1600). The protein formed high molecular weight aggregates in induced cells of RR28/pNZ1600 but not in RR28/pNZ1447. The enzyme constituted up to 10% of the total cell protein and was located in the cytoplasmic fraction of RR28/pNZ1447. The acetyl esterase was most active at pH 6.0 and 70–75° C with a half-life of 64 h at 70° C and 30 h at 80° C, respectively.Offprint requests to: P. L. Bergquist     

Studies on the Autolysis of Aspergillus oryzae

An intracellular nuclease inhibitor was 1270 times purified from a heat treated cell free extract of fresh mycelia of Aspergillus oryzae, by ammonium sulfate fractionation and chromatographies using DEAE-cellulose and Sephadex G-75. The purified sample of the inhibitor showed a UV absorption curve typical for protein, and it was inactivated by proteases such as chymotrypsin. The inhibitor stoichiometrically inactivated nuclease O (an intracellular nuclease of Asp. oryzae), forming an enzyme-inhibitor complex. But, it did not affect nuclease S₁, RNase T₁, RNase T₂ or pancreatic RNase. The inhibitor was insensitive to 10^?5m p-chloromercuribenzoate or 10^?4m Pb²⁺. Molecular weights estimated by the method of Andrews were 23,000 for the inhibitor, 47,000 for nuclease O, and 82,000 for the enzyme-inhibitor complex. The nuclease activity was recovered from the inactive complex by the action of chymotrypsin.

Nuclease O of Asp. oryzae was purified and crystallized from 113.5 kg of wet mycelia and 2 kl of culture filtrate, by salting out with ammonium sulfate and by chromatographies on CM-Sephadex C-50 and Sephadex G-100. The purified nuclease showed a single peak with apparent sedimentation constant 2.9S in an ultracentrifuge. The molecular weight measured by short column method was 64,000. The nuclease was completely inhibited by the specific nuclease inhibitor obtained from Asp. oryzae. The nuclease was activated by 0.1 mm Mg²⁺ and Mn²⁺, and completely inhibited by 1 mm EDTA. Optimum pH for activity was 7.6 for RNA and 7.4 for DNA. The nuclease degraded polyadenylic acid, polyuridylic acid and polycytidylic acid without forming detectable amount of mononucleotides. And, the main product from RNA was oligonucleotides. The enzyme showed no nonspecific phosphodiesterase activity.     

Formation and release of cellulolytic enzymes during growth of Trichoderma reesei on cellobiose and glycerol

Summary Production and release of cellulolytic enzymes by Trichoderma reesei QM 9414 were studied under induced and non-induced conditions. For that purpose, a method was developmed to produce cellulases by Trichoderma reesei QM 9414 using the soluble inducer, cellobiose, as the only carbon source. The production was based on continuous feeding of cellobiose to a batch culture. For optimum production, the cellobiose supply had to be adjusted according to the consumption so that cellobiose was not accumulated in the culture. With a proper feeding program the repression and/or inactivation by cellobiose could be avoided and the cellulase production by Trichoderma reesei QM 9414 was at least equally as high as with cellulose as the carbon source.During the cultivation, specific activities against filter paper, carboxymethyl cellulose (CMC) and p-nitrophenyl glucoside were analyzed from the culture medium as well as from the cytosol and the cell debris fractions. There was a base level of cell debris bound hydrolytic activity against filter paper and p-nitrophenyl glucoside even in T. reesei grown non-induced on glycerol. T. reesei grown on cellobiose was induced to produce large amounts of extracellular filter paper and CMC hydrolyzing enzymes, which were actively released into the medium even in the early stages of cultivation. -Glucosidase was mainly detected in the cell debris and was not released unless the cells were autolyzing.     

Promotion of Efficient Saccharification of Crystalline Cellulose by Aspergillus fumigatus Swo1

Swollenin is a protein from Trichoderma reesei that has a unique activity for disrupting cellulosic materials, and it has sequence similarity to expansins, plant cell wall proteins that have a loosening effect that leads to cell wall enlargement. In this study we cloned a gene encoding a swollenin-like protein, Swo1, from the filamentous fungus Aspergillus fumigatus, and designated the gene Afswo1. AfSwo1 has a bimodular structure composed of a carbohydrate-binding module family 1 (CBM1) domain and a plant expansin-like domain. AfSwo1 was produced using Aspergillus oryzae for heterologous expression and was easily isolated by cellulose-affinity chromatography. AfSwo1 exhibited weak endoglucanase activity toward carboxymethyl cellulose (CMC) and bound not only to crystalline cellulose Avicel but also to chitin, while showing no detectable affinity to xylan. Treatment by AfSwo1 caused disruption of Avicel into smaller particles without any detectable reducing sugar. Furthermore, simultaneous incubation of AfSwo1 with a cellulase mixture facilitated saccharification of Avicel. Our results provide a novel approach for efficient bioconversion of crystalline cellulose into glucose by use of the cellulose-disrupting protein AfSwo1.Cellulose is the primary polysaccharide of plant cell wall and the most abundant renewable biomass resource. Biological degradation of cellulose to soluble sugars has long been considered an alternative to the use of starch feedstocks for bioethanol production. Natural cellulose is an ordered, linear polymer of thousands of d-glucose residues linked by β-1,4-glucosidic bonds. Spontaneous crystallization of cellulose molecules due to chemical uniformity of glucose units and the high degree of hydrogen bonding in cellulose can often result in the formation of tightly packed microfibrils (8), which remain inaccessible to cellulolytic enzymes. No single enzyme is able to hydrolyze crystalline cellulose microfibrils completely. Synergistic effects of cellulase mixtures on crystalline cellulose degradation are well known (1, 7, 21). Nevertheless, cost-competitive technology for overcoming the recalcitrance of cellulosic biomass to enhance enzymatic saccharification is still a major impediment to the utilization of cellulosic materials in bioenergy generation.Expansins are plant cell wall proteins that cause cell wall enlargement by a unique loosening effect in an acid-induced manner (15, 20). They are also involved in many physiological processes where cell wall extension occurs, such as pollination, fruit ripening, organ abscission, and seed germination (13, 14). It has been proposed that plant expansins disrupt hydrogen bonding between cellulose microfibrils and other cell wall polysaccharides without hydrolytic activity, causing sliding of cellulose fibers or expansion of the cell wall (18, 19, 27). Swollenin, an expansin-like protein, was isolated and characterized from the cellulolytic filamentous fungus Trichoderma reesei. It has a bimodular structure consisting of a carbohydrate-binding module family 1 (CBM1) domain and an expansin-like domain connected by a linker region rich in serine and threonine. Swollenin exhibits disruption activity on cellulosic materials such as cotton and algal cell walls without releasing any detectable reducing sugars (23). However, effects of cellulose disruption activity on degradation/saccharification of crystalline cellulose have not yet been reported.Here, we report cloning a swollenin-like gene (designated Afswo1) from the filamentous fungus Aspergillus fumigatus. We also report its production by Aspergillus oryzae and characterization of the purified AfSwo1.     

Characterization of the tea fungus metabolites

Summary The tea fungus (commonly designed as kombucha) is a symbiotic culture of at least three microorganisms: the acetic acid bacteria Acetobacter xylinum and two yeasts Zygosaccharomyces rouxii and Candida sp. in sugared tea (Hesseltine, 1965; Anonymous, 1983). These microorganisms were cultured in their traditional medium and several metabolites were identified and quantified : ethanol, lactic, acetic, gluconic and glucuronic acids. The antibacterial product known as usnic acid was also searched.     

Evidence for disaggregation of oligomeric G(o)alpha induced by guanosine-5;-3-O-(thio)triphosphate activation

Myristoylated G_o was expressed in and highly purified from Escherichia coli strain JM109 cotransformed with pQE60 (G_o) and pBB131 (N-myristoyltransferase, NMT). Non-denaturing gel electrophoresis and gel filtration analysis revealed that the G_o, in its GDP-bound form, could form oligomers involving dimer, trimer, tetramer, pentamer, or hexamer and guanosine 5"-3-O-(thio)triphosphate (GTPS) activation induced disaggregation of the G_o oligomers to monomers. The G_o was crosslinked by a cross-linker, N,N"-1,4-phenylenedimaleimide (p-PDM), yielding multiple crosslinked products. In contrast, no obvious cross-linking occurred when G_o was pretreated with GTPS. Immunoblot analysis also demonstrated oligomerization of the purified G_o proteins and its disaggregation triggered by GTPS. These results provided direct evidence for the disaggregation–coupling theory and the disaggregation action of GTPS may further elucidate the regulatory role of GDP/GTP exchange in G protein-coupled signal transduction pathways.     

Characterization of an Aspartic Proteinase of Mucor pusillus expressed in Aspergillus oryzae

The aspartic proteinase (MPP) gene from the zygomycete fungus Mucor pusillus was introduced into an ascomycete fungus, Aspergillus oryzae, by protoplast transformation using the nitrate reductase (niaD) gene as the selective marker. Southern blot analysis indicated that the MPP gene was integrated into the resident niaD locus at a copy number of 1–2. MPP secreted by the recombinant A. oryzae was correctly processed but was more highly glycosylated than that produced in the original M. pusillus strain. Treatment with endo--N-acetyl-glucosaminidase H and analysis of the carbohydrate composition of the secreted MPP revealed that the extra glycosylation of the MPP secreted by the recombinant A. oryzae was due to altered processing of mannose residues. The extra glycosylation of MPP affected its enzyme properties including its milk-clotting and proteolytic activities.