微紫青霉CBHⅠ基因(Cbh1)在体外无细胞系统中的表达

以含Ｃｂｈ１的ｐＵＣ１８－１８１ ＤＮＡ 为模板,经ＰＣＲ扩增得到带有Ｔ７启动子的Ｃｂｈ１片段,随后在缺乏糖基化的兔网织红细胞裂解液中得到成功表达,表达量为２１．７ μｇ／ｍ ｌ．得到的ＣＢＨ Ⅰ虽未经糖基化修饰,却可水解对硝基酚－β－Ｄ－纤维二糖苷（ｐＮＰＣ）,对ｐＮＰＣ的ＫＭ 和Ｖｍ ａｘ分别为０．８２ｍ ｍ ｏｌ／Ｌ和０．０６７ μｍ ｏｌ·ｍ ｉｎ－ １·μｇ－ １,但对羧甲基纤维素钠（ＣＭＣ－Ｎａ）无酶活力．这表明,糖基化修饰可能不影响胞外纤维素酶的活力．     

Identification and purification of the main components of cellulases from a mutant strain of Trichoderma viride T 100-14

A new mutant strain of fungus Trichoderma viride T 100-14 was cultivated on 1% microcrystalline cellulose (Avicel) for 120h and the resulting culture filtrate was prepared for protein identification and purification. To identify the predominant catalytic components, cellulases were separated by an adapted two-dimensional electrophoresis technique. The apparent major spots were identified by high performance liquid chromatography electrospray ionization mass (HPLC-ESI-MS). Seven of the components were previously known, i.e., the endoglucanases Cel7B (EG I), Cel12A (EG III), Cel61A (EG IV), the cellobiohydrolases Cel7A (CBH I), Cel6A (CBH II), Cel6B (CBH IIb) and the beta-glucosidase. The seven major components in the fermentation broth of T. viride T 100-14 probably constitute the essential enzymes for crystalline cellulose hydrolysis and they were further purified to electrophoretic homogeneity by a series of chromatography column. Hydrolysis studies of the purified elements revealed that three of the cellulases were classified as cellobiohydrolases due to their main activities on p-nitrophenyl-beta-d-cellobioside (pNPC). Three of the cellulases, with the abilities of hydrolyzing both carboxymethyl-cellulose (CMC) and Avicel indicate their endoglucanase activities. It deserved noting that the beta-glucosidase from the T 100-14 displayed an extremely high activity on p-nitrophenyl-beta-D-glycopyranoside (pNPG), which suggested it was a good candidate for the conversion of cellobiose to glucose.     

Recombinant Cellulase Accumulation in the Leaves of Mature,Vegetatively Propagated Transgenic Sugarcane

The cost of enzymes that hydrolyse lignocellulosic substrates to fermentable sugars needs to be reduced to make cellulosic ethanol a cost-competitive liquid transport fuel. Sugarcane is a perennial crop and the successful integration of cellulase transgenes into the sugarcane production system requires that transgene expression is stable in the ratoon. Herein, we compared the accumulation of recombinant fungal cellobiohydrolase I (CBH I), fungal cellobiohydrolase II (CBH II), and bacterial endoglucanase (EG) in the leaves of mature, initial transgenic sugarcane plants and their mature ratoon. Mature ratoon events containing equivalent or elevated levels of active CBH I, CBH II, and EG in the leaves were identified. Further, we have demonstrated that recombinant fungal CBH I and CBH II can resist proteolysis during sugarcane leaf senescence, while bacterial EG cannot. These results demonstrate the stability of cellulase enzyme transgene expression in transgenic sugarcane and the utility of sugarcane as a biofactory crop for production of cellulases.     

The competitive inhibition of Trichoderma reesei C30 cellobiohydrolase I by guanidine hydrochloride

TheP-nitrophenylcellobiosidase (PNPCase) activity of Trichoderma reesei cellobiohydrolase I (CBH I) was competitively inhibited by concentrations of guanidine hydrochloride (Gdn HC1) that did not affect the tryptophan fluorescence of this enzyme. The K_m of CBH I, 3.6 mM, was increased to 45.4 mM in the presence of 0.14 M Gdn HCl, the concentration that was required to inhibit the enzyme by 50%. A similar concentration of lithium chloride and urea had little effect on the PNPCase activity of CBH I. Maximal inhibition was pH dependent, occurring in the range of pH 4.0 to 5.0, which is in the range for maximal activity. Analysis of the inhibition data indicated that 1.2 molecules of Gdn HCl combine reversibly with I molecule of CBH I. Other hydrolases and proteases were also inhibited by Gdn HCl. It is suggested that the inhibition of CBH I by Gdn HCl occurs as a result of the interaction between the positively charged guanidinium group of Gdn HCl and the carboxylate group of glutamic acid 126, postulated to be in the catalytic center of this enzyme.     

Strategy for Identification of Novel Fungal and Bacterial Glycosyl Hydrolase Hybrid Mixtures that can Efficiently Saccharify Pretreated Lignocellulosic Biomass

A rational four-step strategy to identify novel bacterial glycosyl hydrolases (GH), in combination with various fungal enzymes, was applied in order to develop tailored enzyme cocktails to efficiently hydrolyze pretreated lignocellulosic biomass. The fungal cellulases include cellobiohydrolase I (CBH I; GH family 7A), cellobiohydrolase II (CBH II; GH family 6A), endoglucanase I (EG I; GH family 7B), and β-glucosidase (βG; GH family 3). Bacterial endocellulases (LC1 and LC2; GH family 5), β-glucosidase (LβG; GH family 1), endoxylanases (LX1 and LX2; GH family 10), and β-xylosidase (LβX; GH family 52) from multiple sources were cloned, expressed, and purified. Enzymatic hydrolysis for varying enzyme combinations was carried out on ammonia fiber expansion (AFEX)-treated corn stover at three total protein loadings (i.e., 33, 16.5, and 11 mg enzyme/g glucan). The optimal mass ratio of enzymes necessary to maximize both glucan and xylan yields was determined using a suitable design of experiments. The optimal hybrid enzyme mixtures contained fungal cellulases (78% of total protein loading), which included CBH I (loading ranging between 9-51% of total enzyme), CBH II (9-51%), EG I (10-50%), and bacterial hemicellulases (22% of total protein loading) comprising of LX1 (13%) and LβX (9%). The hybrid mixture was effective at 50°C, pH 4.5 to maximize saccharification of AFEX-treated corn stover resulting in 95% glucan and 65% xylan conversion. This strategy of screening novel enzyme mixtures on pretreated lignocellulose would ultimately lead to the development of tailored enzyme cocktails that can hydrolyze plant cell walls efficiently and economically to produce cellulosic ethanol.     

Adsorption and synergism of cellobiohydrolase I and II of Trichoderma reesei during hydrolysis of microcrystalline cellulose

Hydrolysis of microcrystalline cellulose (Avicel) by cellobiohydrolase I and II (CBH I and II) from Trichoderma reesei has been studied. Adsorption and synergism of the enzymes were investigated. Experiments were performed at different temperatures and enzyme/substrate ratios using CBH I and CBH II alone and in reconstituted equimolar mixtures. Fast protein liquid chromatography (FPLC) analysis was found to be an accurate and reproducible method to follow the enzyme adsorption. A linear correlation was found between the conversion and the amount of adsorbed enzyme when Avicel was hydrolyzed by increasing amounts of CBH I and/or CBH II. CBH I had lower specific activity compared to CBH II although, over a wide concentration range, more CBH I was adsorbed than CBH II. Synergism between the cellobiohy-drolases during hydrolysis of the amorphous fraction of Avicel showed a maximum as a function of total enzyme concentration. Synergism measured as a function of bound enzyme showed a continuous increase, which indicates that by decreasing the distance between the two enzymes the synergism is enhanced. The adsorption process for both enzymes was slow. Depending on the enzyme/substrate ratio it took 30-90 min to reach 95% of the equilibrium binding. The amount of bound enzyme decreased with increasing temperature. The two enzymes compete for the adsorption sites but also bind to specific sites. Stronger competition for adsorption sites was shown by CBH I. (c) 1994 John Wiley & Sons, Inc.     

Mode of action of cellulases on dyed cotton with a reactive dye

Cotton woven fabrics which were previously dyed with a reactive dye were treated with a commercial cellulase preparation. Dyeing with a reactive dye for cotton apparently inhibited the weight loss activity and saccharification activity of cellulase. In addition, dyed cotton was treated with highly purified cellulases which were exo-type cellulases (Cellobiohydrolase I (CBH I) and Cellobiohydrolase II (CBH II)) and endo-type cellulase (Endoglucanase II (EG II)). Exo-type cellulases were inhibited more than endo-type cellulase by dyeing in the case of saccharification activity. CBH I was severely inhibited by dyeing as compared with CBH II or EG II from the viewpoint of morphological changes in the fiber surface. Dyes on the cellulose substrates severely influenced CBH I in spite of the rare modification, because CBH I hydrolyzed cellulose with true-processive action. The change in the activity of each cellulase component on dyed cotton can affect the synergistic action of cellulases.     

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.     

SCHEMA Recombination of a Fungal Cellulase Uncovers a Single Mutation That Contributes Markedly to Stability

A quantitative linear model accurately (R² = 0.88) describes the thermostabilities of 54 characterized members of a family of fungal cellobiohydrolase class II (CBH II) cellulase chimeras made by SCHEMA recombination of three fungal enzymes, demonstrating that the contributions of SCHEMA sequence blocks to stability are predominantly additive. Thirty-one of 31 predicted thermostable CBH II chimeras have thermal inactivation temperatures higher than the most thermostable parent CBH II, from Humicola insolens, and the model predicts that hundreds more CBH II chimeras share this superior thermostability. Eight of eight thermostable chimeras assayed hydrolyze the solid cellulosic substrate Avicel at temperatures at least 5 °C above the most stable parent, and seven of these showed superior activity in 16-h Avicel hydrolysis assays. The sequence-stability model identified a single block of sequence that adds 8.5 °C to chimera thermostability. Mutating individual residues in this block identified the C313S substitution as responsible for the entire thermostabilizing effect. Introducing this mutation into the two recombination parent CBH IIs not featuring it (Hypocrea jecorina and H. insolens) decreased inactivation, increased maximum Avicel hydrolysis temperature, and improved long time hydrolysis performance. This mutation also stabilized and improved Avicel hydrolysis by Phanerochaete chrysosporium CBH II, which is only 55–56% identical to recombination parent CBH IIs. Furthermore, the C313S mutation increased total H. jecorina CBH II activity secreted by the Saccharomyces cerevisiae expression host more than 10-fold. Our results show that SCHEMA structure-guided recombination enables quantitative prediction of cellulase chimera thermostability and efficient identification of stabilizing mutations.SCHEMA is a computational approach to identifying blocks of sequence that minimize structural disruption when they are recombined in chimeric proteins (1). SCHEMA recombination of eight blocks from three fungal cellobiohydrolase class II (CBH II)² genes was used in our previous work to create a library of 3⁸ = 6,561 chimeric sequences, all having the native Hypocrea jecorina cellulose binding module and linker and observed to feature a degree of glycosylation similar to that found in native CBH IIs secreted by fungi (2). Synthesis and characterization of selected CBH II chimeras expressed in Saccharomyces cerevisiae revealed enzymes with thermostabilities and cellulose hydrolysis performance superior to those of the parent enzymes from Humicola insolens, H. jecorina, and Chaetomium thermophilum.Our prior analysis showed that a qualitative model based on sequence-stability data from 23 functional chimeras (categorizing blocks as destabilizing, stabilizing, or neutral) could identify highly stable chimeras in the SCHEMA library (2). When studying SCHEMA recombination of a bacterial cytochrome P450, we previously estimated that building a quantitative regression model would require stability measurements for at least 35 representative sequences (3). We therefore synthesized an additional 18 CBH II chimeras to further explore the sequences that the qualitative model predicted would encode the most thermostable chimeras. If sequence blocks contribute additively and independently of their context, as was found for SCHEMA chimeras of cytochrome P450 (3), then quantitative stability prediction would be possible based on stability data from a very limited sampling of the thousands of possible chimeras. Here we show that a quantitative CBH II chimera stability model can in fact be constructed and also that it was possible, using site-directed mutagenesis experiments, to pinpoint a single amino acid substitution that is responsible for the large stabilizing contribution of one of the SCHEMA blocks.Highly thermostable fungal CBH IIs are potentially useful for the degradation of cellulosic substrates in biofuels, textile, and other applications (4). High thermostability translates to longer half-lives at elevated hydrolysis temperatures, where viscosity and microbial contamination are reduced (5). We therefore investigated how selected thermostable CBH II chimeras perform in the hydrolysis of crystalline cellulose (Avicel) at elevated temperatures (up to 70 °C). All of the thermostable chimeras tested have specific activities on phosphoric acid swollen cellulose (PASC) at 50 °C that are comparable with the most active parent (H. jecorina CBH II) and hydrolyze Avicel at temperatures higher than any of the three parent enzymes, including the CBH II from the thermophilic fungus H. insolens.     

Cloning,sequencing, and heterologous expression of a cellobiohydrolase cDNA from the basidiomycete Corticium rolfsii

From a Corticium rolfsii cDNA library, a clone homologous to other fungal cellobiohydrolase (CBH1) genes was isolated using the polymerase chain reaction. In the nucleotide sequence, one 1.6 kb long open reading frame coding for a polypeptide of 530 amino acid residues was detected which showed 64% identity with CBH1 of Phanerochaete chrysosporium. With expression of the 1.8 kb cDNA using the Aspergillus oryzae expression system, we detected microcrystalline cellulose (Avicel) hydrolyzing activity in the culture supernatant. The secreted protein, accompanied by the activity, was 89 kDa by SDS-polyacrylamide gel electrophoresis.     

Synergistic cooperation of cellulases of trichoderma reesei as distinguished by a new filter-paper destruction assay

WHATMAN 1 CHR filter paper manufactured from macerated cotton fibers was shown to be a soft substrate when broken down by purified cellulases of Trichoderma reesei (CELLUCLAST). Destruction of filter-paper disks was induced by CBH I/1, CBH I/2, CBH II/1, CBH II/2, and EG I in a macroscopic assay. Attack on disks by mixtures of these cellulases (CBH I/1 or CBH I/2 mixed with CBH II/1, CBH II/2, or with EGJ) were followed by synergistically enhanced destructions. SCHLEICHER &SCHUELL filter paper No 595 was shown to be a harder substrate of enzymatical decomposition when induced by cellulases of CELLUCLAST. None of the cellulases could induce macroscopic destruction of filter-paper disks when acting in isolation. However, mixtures of isolated exo and endo-glucanases (CBH I/1 or CBH I/2 mixed with CBH II/1, CBH II/2, or EG I) caused powerful destruction of filter-paper disks. SCHLEICHER &SCHUELL filter paper No 595 incubated first with an endo-glucanase (CBH II/1, CBH II/2, EG I) and treated in a secondary incubation with an exo-glucanase (CBH I/1, CBH I/2) were destroyed to a greater extent than with incubations executed in the reverse order. Results confirm the endo exo concept of explaining cellulose decomposition. The filter-paper destruction assay was performed with filter-paper disks prepared with an office punch. Disks were incubated in 1 ml EPPENDORF reaction tubes filled up beforehand with 0.4 or 0.5 ml of enzyme solution. The degree of synergism of cellulases resulted from the assay in the range of 300 to 1 300 p.c.     

Identification of glycan structure and glycosylation sites in cellobiohydrolase II and endoglucanases I and II from Trichoderma reesei

Mass spectrometric techniques combined with enzymatic digestions were applied to determine the glycosylation profiles of cellobiohydrolase (CBH II) and endoglucanases (EG I, II) purified from filamentous fungus Trichoderma reesei. Electrospray mass spectrometry (ESMS) analyses of the intact cellulases revealed the microheterogeneity in glycosylation where glycoforms were spaced by hexose units. These analyses indicated that glycosylation accounted for 12-24% of the molecular mass and that microheterogeneity in both N- and O-linked glycans was observed for each glycoprotein. The identification of N-linked attachment sites was carried out by MALDI-TOF and capillary liquid chromatography-ESMS analyses of tryptic digests from each purified cellulase component with and without PNGase F incubation. Potential tryptic glycopeptide candidates were first detected by stepped orifice-voltage scanning and the glycan structure and attachment site were confirmed by tandem mass spectrometry. For purified CBH II, 74% of glycans found on Asn310 were high mannose, predominantly Hex(7-9)GlcNAc(2), whereas the remaining amount was single GlcNAc; Asn289 had 18% single GlcNAc occupancy, and Asn14 remained unoccupied. EG I presented N-linked glycans at two out of the six potential sites. The Asn56 contained a single GlcNAc residue, and Asn182 showed primarily a high-mannose glycan Hex(8)GlcNAc(2) with only 8% being occupied with a single GlcNAc. Finally, EG II presented a single GlcNAc residue at Asn103. It is noteworthy that the presence of a single GlcNAc in all cellulase enzymes investigated and the variability in site occupancy suggest the secretion of an endogenous endo H enzyme in cultures of T. reesei.     

Production and Characteristics of Avicel-Digesting and Non-Avicel-Digesting Cellobiohydrolases from Aspergillus ficum

Two immunologically related cellobiohydrolases, cellobiohydrolase I (CBH I) and cellobiohydrolase II (CBH II), were purified from Aspergillus ficum. The Avicel-adsorbable CBH I (molecular weight, 128,000) digested Avicel, cotton, and cellulose powder to cellobiose, but the Avicel-unadsorbable CBH II (molecular weight, 50,000) could not digest those substrates. Both enzymes hydrolyzed insoluble cellooligosaccharides ( 25) to cellobiose. High-pressure liquid chromatographic analysis of soluble cellooligosaccharide hydrolysates revealed that both enzymes split off strictly cellobiose units from the nonreducing end of the cellulose chain with an exowise mechanism. CBH I showed glucosyltransferase activity, but CBH II did not. The N-bromosuccinimideoxidized CBH I was completely inactive but retained the ability to adsorb to Avicel. This suggested that CBH I has separate sites for binding to cellulose and for catalyzing cleavage of glycosidic linkages. Cellobiohydrolases were of two types, CBH I and CBH II. The former can adsorb to and digest Avicel, while the latter can do neither.     

Synergism of isoenzymes of cellobiohydrolase I and II of trichoderma reesei in hydrolysis of amorphous cellulose

Decompositions of amorphous cellulose induced by cellulases of Trichoderma reesei were evaluated from gradients at zero time of exponential functions which were fitted to nephelometrically measured values of turbidty of incubated solutions of cellulose [turbidity = A × exp (B × t)+ C [A, B, C = constants, t = time]]. Synergistic enhancements of decomposition of amorphous cellulose resulted in the range of 300 p.c. whenever of the two isoenzymes of cellobiohydrolase I of Trichoderma reesei (CBH I, being an exo-glucanase) one was incubated together with one of the isoenzymes of CBH II (being really an endo-glucanase). Accessibility of amorphous cellulose to enzymatic decomposition being calculated from the fitted function by the term (A/(A + C)) × 100 [p.c.] resulted for the CBH I isoenzymes and for the CBH II/1 in the range of 27 to 38 p.c. of the total substrate. Incubations of CBH II/1 in with CBH I/1 and CBH I/2 were followed by increases of accessibility to 85 and 87 p.c., respectively. CBH II/2 by itself caused a substrate accessibility in the range of 80 p.c., which increased to 96 p.c. when it was incubated together with CBH I/1 or CBH I/2. Amorphous cellulose dispersing activity (ACD activity) being evaluated from the fitted function by the term (A + C)/(A_c + C_c) × 100 [p.c.] (A_c + C_c × control turbidity at zero time) was not increased when a CBH I isoenzyme was incubated together with a CBH II isoenzyme. EG I, a convetional endo-glucanase from Tr. reesei proved not to act synergistically in any case when incubated together with one of the CBH isoenzymes. On the contrary, EG I turned out to act antagonistically to CBH II/1 and CBH II/2. Results can be interpreted as an exo-endo-synergism taking place between C₁-specific exo- and endo-glucanases.     

Cellulase Complex of the Fungus Chrysosporium lucknowense: Isolation and Characterization of Endoglucanases and Cellobiohydrolases

Using different chromatographic techniques, eight cellulolytic enzymes were isolated from the culture broth of a mutant strain of Chrysosporium lucknowense: six endoglucanases (EG: 25 kD, pI 4.0; 28 kD, pI 5.7; 44 kD, pI 6.0; 47 kD, pI 5.7; 51 kD, pI 4.8; 60 kD, pI 3.7) and two cellobiohydrolases (CBH I, 65 kD, pI 4.5; CBH II, 42 kD, pI 4.2). Some of the isolated cellulases were classified into known families of glycoside hydrolases: Cel6A (CBH II), Cel7A (CBH I), Cel12A (EG28), Cel45A (EG25). It was shown that EG44 and EG51 are two different forms of one enzyme. EG44 seems to be a catalytic module of an intact EG51 without a cellulose-binding module. All the enzymes had pH optimum of activity in the acidic range (at pH 4.5-6.0), whereas EG25 and EG47 retained 55-60% of the maximum activity at pH 8.5. Substrate specificity of the purified cellulases against carboxymethylcellulose (CMC), beta-glucan, Avicel, xylan, xyloglucan, laminarin, and p-nitrophenyl-beta-D-cellobioside was studied. EG44 and EG51 were characterized by the highest CMCase activity (59 and 52 U/mg protein). EG28 had the lowest CMCase activity (11 U/mg) amongst the endoglucanases; however, this enzyme displayed the highest activity against beta-glucan (125 U/mg). Only EG51 and CBH I were characterized by high adsorption ability on Avicel cellulose (98-99%). Kinetics of Avicel hydrolysis by the isolated cellulases in the presence of purified beta-glucosidase from Aspergillus japonicus was studied. The hydrolytic efficiency of cellulases (estimated as glucose yield after a 7-day reaction) decreased in the following order: CBH I, EG60, CBH II, EG51, EG47, EG25, EG28, EG44.     

A novel PCR-based approach for the detection and classification of potential cellulolytic fungal strains isolated from museum items and surrounding indoor environment

Aims: To develop a novel PCR‐based method able to detect potential cellulolytic filamentous fungi and to classify them exploiting the amplification of the cellobiohydrolase gene (cbh‐I) and its polymorphism. Methods and Results: A mixed approach including the combination of (i) fungal cultivation and isolation, (ii) classification of fungal isolates through the amplification of the cbh gene using a fluorescently labelled primer (f‐CBH‐PCR) and (iii) final fungal identification based on amplification and sequencing of the ITS1‐5.8S rDNA‐ITS2 region of the selected fungal strains was developed. By this approach, it was possible to screen 77 fungal strains belonging to 14 genera and 26 species. Conclusions: The f‐CBH‐PCR permitted the discrimination of fungal species, producing typical f‐CBH profiles. Significance and Impact of the Study: In this study, the cbh gene was used as a preliminary classification tool able to differentiate among themselves the fungal members isolated from indoor museum items and surrounding environment. Such mixed approach consented the fast identification of all isolated fungal strains. The f‐CBH‐PCR method demonstrated its discrimination power, and it can be considered as a new molecular system suitable for the classification of fungal strains isolated from different environments.     

Cellobiohydrolase I (Cel7A) from Trichoderma reesei has chitosanase activity

Cellobiohydrolase CBH I (Cel7A) from the filamentous fungus Trichoderma reesei (TrCBHI), which is a member of glycoside hydrolase family (GHF) 7, was expressed in Aspergillus oryzae. We found that the recombinant enzyme showed significant chitosanase activity, as well as cellulase activity, and acted in an endo-type manner on soluble polymeric substrate. Furthermore, another GHF7 CBH I from Aspergillus aculeatus (AaCBHI) expressed in A. oryzae also had chitosanase activity, while endoglucanase EG I (Cel7B) from T. reesei had no activity towards chitosan. To our knowledge, this is the first report of GHF7 enzymes possessing chitosanase activity.     

Purification and properties of two enzymes from Dichomitus squalens which exhibit both cellobiohydrolase and xylanase activity

Two fractions (Ex I and II), exhibiting activity towards p-nitrophenyl β-cellobioside (pNPC) have been isolated by chromatofocusing of the proteins obtained from the supernatant solution of a cellulose-containing culture of the white-rot fungus Dichomitus squalens. They were further purified up to 16.0- and 14.2-fold by chromatography on Phenyl-Sepharose CL-4B and ion-exchange chromatography on DEAE-Trisacryl. Each purified enzyme gave a single peak for protein and activity on chromatography on Ultrogel AcA-54 and a single protein band in disc gel electrophoresis, in the absence and presence of sodium dodecyl sulphate, and on isoelectrofocusing. The mol. wts. of Ex I and II were 39,000 and 36,000, respectively, and their isoelectric points were 4.6 and 4.5, respectively. Maximum activity towards pNPC was shown at pH 5.0 and 60°, and each enzyme was stable over the pH range 4.0–8.0, and up to 70° and 60° for Ex I and II, respectively. The enzymes cleaved pNPC, released mainly cellobiose from cellulose, were especially active towards xylan and o-nitrophenyl β-d-xylopyranoside, and exhibited strong transglycosylating activities.     

Purification and characterization of a novel cellobiohydrolase (PdCel6A) from Penicillium decumbens JU-A10 for bioethanol production

An acidic Cel6A, cellobiohydrolase (CBH) II, was purified from Penicillium decumbens and designated as PdCel6A. The deduced internal amino acid sequence of the novel CBH has a high degree of sequence identity with the CBH II from Aspergillus fumigatus. Surprisingly, PdCel6A exhibits characteristics comparable to that of CBH I, as well as CBH II. Similar to CBH I, the novel CBH has a specific activity of 1.9 IU/mg against p-nitrophenyl-β-d-cellobioside. The enzyme retains about 80% of its maximum activity after 4h of incubation at pH 2.0. Using delignified corncob residue as the substrate, ethanol concentration increased by 20% during simultaneous saccharification and fermentation when supplemented with low doses of PdCel6A (0.2mg/g substrate). To our knowledge, this is the first report involving a CBH I-like CBH II. The present paper provides new insight into the role of CBH II in cellulose degradation.