Adsorption of cellulase from Trichoderma viride on cellulose

The adsorption of cellulase from Trichoderma viride (Meicelase CEP) on the surface of pure cellulose was studied. The adsorption was found to obey apparently the Langmuir isotherm. From the data concering the effects of temperature and the crystallinity of cellulose on the Langmuir adsorption parameters, the characteristics of the adsorption of the individual cellulase components, namely CMCase (endoglucanase) and Avicelase (exoglucanase), were discussed. While beta-glucosidase also adsorbed on the surface of cellulose at 5 degrees C, it did not at 50 degrees C.     

Biodegradation of wastepaper by cellulase from Trichoderma viride

Environmental issues such as the depletion of non-renewable energy resources and pollution are topical. The extent of solid waste production is of global concern and development of its bioenergy potential can combine issues such as pollution control and bioproduct development, simultaneously. Various wastepaper materials, a major component of solid waste, were treated with the cellulase enzyme from Trichoderma viride, thus bioconverting their cellulose component into fermentable sugars. All wastepaper materials exhibited different susceptibilities towards the cellulase as well as the production of non-similar sugar releasing patterns when increasing amounts of paper were treated with a fixed enzyme concentration. The hydrolysis of wastepaper with changing enzyme concentrations and incubation periods also resulted in dissimilar sugar-producing tendencies. A general decline in hydrolytic efficiency was observed when increasing sugar concentrations were produced during biodegradation of all wastepaper materials.     

Strain improvement for enhanced production of cellulase in Trichoderma viride

The filamentous fungi Trichoderma species produce extracellular cellulase. The current study was carried out to obtain an industrial strain with hyperproduction of cellulase. The wild-type strain, Trichoderma viride TL-124, was subjected to successive mutagenic treatments with UV irradiation, low-energy ion beam implantation, atmospheric pressure non-equilibrium discharge plasma (APNEDP), and N-methyl-N'-nitro-N-nitrosoguanidine to generate about 3000 mutants. Among these mutants, T. viride N879 strain exhibited the greatest relevant activity: 2.38-fold filter paper activity and 2.61-fold carboxymethyl cellulase, 2.18-fold beta-glucosidase, and 2.27-fold cellobiohydrolase activities, compared with the respective wild-type activities, under solid-state fermentation using the inexpensive raw material wheat straw as a substrate. This work represents the first application of APNEDP in eukaryotic microorganisms.     

A method for increasing cellulase production by Trichoderma viride

A doubling of cellulase production by Trichoderma viride (QM9414) is possible by increasing the cellulose concentration in the medium from 0.75 to 2%, increasing the nitrogen concentration, and controlling pH during growth. A four-to fivefold increase in β -glucosidase is found with the higher cellulose concentration. Culture filtrates from 2% cellulose cultures can reduce the hydrolysis time in a practical saccharification to one-half that required by culture filtrates from 0.75% cellulose cultures.     

Transglycosylation of cellobiose by partially purified Trichoderma viride cellulase.

A commercial cellulase from Trichoderma viride was fractionated into three fractions, F1, F2, and F3, in order to investigate transglycosylation activities. Among these fractions, F3, which demonstrated highly hydrolytic activity toward p-nitrophenyl beta-D-glucopyranoside and Avicel, most effectively catalyzed the transglycosylation of cellobiose and converted cellobiose into beta-Glc-(1-->6)-beta-glc-(1-->4)-Glc and beta-Glc-(1-->6)-beta-Glc-(1-->6)-beta-Glc(1-->4)-Glc. The F3 fraction contained the enzyme to catalyze beta-glucosyl transfer toward only the C-6 position of the sugar acceptor, and thus it is expected to be of use for syntheses of functional oligosaccharides.     

Partial proteolysis of some cellulase components from Trichoderma viride and the substrate specificity of the modified products.

An endo-cellulase component [EC 3.2.1.4] or random type, F II, was obtained from "Cellulase Onozuka," a commercial product from Trichoderma viride, and was subjected to partial proteolysiats with a protease preparation of the same fungal origin. The resulting modified cellulase was fractioned by two steps of column chromatography, and the resulting patterns, together with the substrate specificity expressed in terms of the randomness of CMC hydrolysis and the immunological properties against anti-F II-rabbit se-um, were examined. The chromatographic patterns were very similar to those of cellulase subfractions without proteolytic treatment. Moreover, the immunological response of the modified cellulases from F II was mostly positive and their randomness of CMC hydrolysis was generally lower, compared with subfractions of F II which were not subjected to proteolysis. The subfractions of Peak III, which were obtained from F II by proteolysis, showed mostly negative immunological response and higher randomness of CMC hydrolysis compared with subfractions of Peak III which were not subjected to proteolysis. Thus, some limited proteolysis of cellulase components may, at least in part, be responsible for its multiplicity in vivo.     

Enzymatic treatment of primary municipal sludge with Trichoderma viride cellulase

Enzymatic hydrolysis of the cellulose in raw primary settled municipal sludge by Trichoderma viride cellulase achieved conversions of up to 75% of the cellulose, primarily to cellobiose, in 24 hr. Simultaneously the gel-like characteristic of raw primary sludge was changed to that of a slurry of fine particles in less than 2 hr, causing a radical change in the ability to ultrafilter the sludge. The use of raw primary sludge as a growth medium for T. viride cellulase production was also investigated. It was possible, with nitrogen supplements, to obtain an enzyme with a filter paper activity (FPA) of two compared to over four which is attainable on defined medium of similar strength. The potential use of cellulase treatment as a pretreatment or integral part of waste treatment processes is discussed and the alternatives evaluated.     

Enhanced cellulase production of the Trichoderma viride mutated by microwave and ultraviolet

Cellulase-producing fungi Trichoderma viride were cultured and fermented on the solid-state wheat bran fermentation medium. The characteristics of its carboxymethyl cellulase (CMCase) in the condition of this solid-state fermentation were evaluated, and the optimum culture time, optimum pH and optimum temperature for CMCase activity of T. viride fermented in this solid state were 60 h, 5.0 and 50 °C, respectively. Carboxymethyl cellulose sodium (CMC-Na) and Congo red were used to screen the strains that had stronger ability to produce enzymes. After the compound mutagenesis by microwave and ultraviolet, seven mutant strains (M-B1–M-B7) were selected and their CMCase activities were assayed. Five of them (M-B1, M-B2, M-B3, M-B5 and M-B7) had significantly stronger ability to produce enzymes than the normal wild type, and they were also very stable for a long period up to 9 generations to produce cellulase. Molecular studies showed that there were some base mutations in endoglucanase I (EG I) genes of mutants M-B1, M-B2, M-B3 and M-B5, but no change in M-B7, suggesting that some amino mutations in EG I proteins caused by base mutations could lead to enhanced cellulase production.     

Growth kinetics and cellulase biosynthesis in the continuous culture of Trichoderma viride.

Continuous culture studies have been carried out growing Trichoderma viride QM 9123 in a 10 liter stirred fermentor on a medium containing commercial glucose as the carbon source. Experiments were carried out at 30 degrees C and at three controlled pH values of 2.5, 3.0, and 4.0 over a range of dilution rates from 0.01 to 0.11 hr-1. Steady-state values of cell, glucose, and cellulase concentration oxygen tension, and outlet gas oxygen partial pressure were recorded. Values of maximum specific growth rate, endogenous metabolism coefficient, Michaelis-Menten coefficient, yield and maintenance coefficient for glucose were derived and correlated the effect of the hydrogen ion concentration. Specific oxygen uptake rates were correlated with specific growth rates and absorption coefficients were shown to be a function of dilution rate independent of pH. Some data on cellulase biosynthesis were examined and correlated in terms of a maturation time model.     

Enzymatic studies on a cellulase system of Trichoderma viride. III. Transglycosylation properties of two cellulase components of random type.

Two highly purified cellulases [EC 3.2.1.4], II-A, and II-B, were obtained from the cellulase system of Trichoderma viride. Both cellulases split cellopentaose retaining the beta-configuration of the anomeric carbon atoms in the hydrolysis products at both pH 3.5 and 5.0. The Km values of cellulases II-A and II-B for cellotetraose were different, but their Vmax values were similar and those for cellooligosaccharides increased in parallel with chain length. Both cellulases produced predominantly cellobiose and glucose from various cellulosic substrates as well as from higher cellooligosaccharides. Cellulase II-A preferentially attacked the holoside linkage of rho-nitrophenyl beta-D-cellobioside, whereas cellulase II-B attacked mainly the aglycone linkage of this cellobioside. Both cellulases were found to catalyze the synthesis of cellotriose from rho-nitrophenyl beta-D-cellobioside by transfer of a glucosyl residue, possibly to cellobiose produced in the reaction mixture. They were also found to catalyze the rapid synthesis of cellotetraose from cellobiose, with accompanying formation of cellotriose and glucose, which seemed to be produced by secondary random hydrolysis of the cellotetraose produced. The capacity to synthesize cellotetraose from cellobiose appeared to be greater with cellulase II-B than with cellulase II-A.     

Production of cellulase and protein from barley straw by Trichoderma viride

The cellulase production by two strains of the cellulolytic fungus Trichoderma viride was examined. The fungi were grown on different preparations of barley straw pretreated with NaOH under high pressure. The production of cellulases and microbial protein by the better strain (QM 9123) was investigated in an aerated 5-liter fermenter under varying stirring rates (200-350 rpm) and straw concentrations (1–2%). The pH was kept between 3.5 and 4.5. The growth of the fungus was followed by measuring the quantity of CO₂ produced and the cell protein. After 2–6 days growth ceased, the lag phases lasting 0–2 days, increasing with increasing straw concentrations. The maximum enzyme yields were reached after 4–10 days. The protein content of the product was 21–26% and up to 70% of the straw was utilized. The yield constants were calculated to be 0.40–0.56; of the same order as those which can be obtained by growing the fungus on glucose.     

Production of cellulase and xylanase by a wild strain of Trichoderma viride

Summary The production of cellulase and xylanase was investigated with a newly isolated strain of Trichoderma viride BT 2169. The medium composition was optimized on a shake-flask scale using the Graeco-Latin square technique. The temperature and time for optimal growth and production of the enzymes in shake cultures were optimized using a central composite design. The temperature optima for maximal production of filter paper cellulase (FPase), xylanase and -gluosidase were 32.8°, 34.7° and 31.1° C, respectively, and the optimum times for production of these enzymes were found to be 144, 158 and 170 h, respectively. The optimized culture medium and conditions (33° C) gave 0.55 unit of FPase, 188.1 units of xylanase and 3.37 units of -glucosidase per milliliter of culture filtrate at 144 h of shake culture. Among different carbon sources tested, the maximum enzyme activities were produced with sulphite pulp and all three enzymes were produced irrespective of the carbon sources used. Batch fermentation in a laboratory fermentor using 2% sulphite pulp allowed the production of 0.61 unit of FPase, 145.0 units of xylanase and 2.72 units of -glucosidase. In a fed-batch fermentation on 6% final Avicel concentration FPase and -glucosidase were 3.0 and 2.4 times higher respectively than those in batch fermentation on 2% Avicel. The pH and temperature optima as well as pH and temperature stabilities of T. viride enzymes were found to be comparable to T. reesei and some other fungal enzymes.     

Enhancement of cellulase production by Trichoderma viride using carbon/nitrogen double-fed-batch

Summary The production of cellulase by Trichoderma viride has been remarkably raised by means of a fed batch fermentation with the addition of cellulose as the carbon source and ammonia as nitrogen source during cultivation.     

Conversion of cellulose to glucose with cellulase of Trichoderma viride ITCC-1433

Trichoderma viride ITCC-1433 secretes a cellulase complex that is rich in β-glucosidase and therefore well suited for the saccharification of cellulosic materials. The cellulase was investigated with respect to optimum conditions of reaction and enzyme stability. Avicelase, CMCase, and β-glucosidase differed considerably in their physicochemical properties. At temperatures above 50°C, β-glucosidase is not very stable. Therefore, as a compromise the conditions of hydrolysis were chosen to be 50°C and pH 4.5. With the crude culture filtrate of T. viride ITCC-1433 a nearly pure glucose solution of 4% is reached from a 10% cellulose suspension. Wood pulp and newsprint are hydrolyzed to a much smaller extent. With an enzyme concentrate up to 8% glucose accumulated in the reaction fluid within 48 hr. At this time the glucose-cellobiose ratio was 75:1. Glucose was demonstrated to be the most potent inhibitor of total hydrolysis. The addition of glucose to the enzyme-substrate solution at zero time completely stopped its own formation and cellobiose and reducing groups (oligosaccharides) accumulated. By removing glucose through an ultrafilter device about 90% saccharification of cellulose to glucose was achieved in 48 hr without any accumulation of cellobiose.     

pH值对绿色木霉(Trichoderma viride)产纤维素酶的影响

采用微晶纤维素为唯一诱导性碳源,对绿色木霉(Trichoderma viride)在摇瓶发酵过程中控制与不控制pH产纤维素酶进行比较.控制pH时胞外蛋白浓度为0.72 mg/mL比不控制pH时提高43%;FPA、EG、GB和CBH酶活为15.0U/mL,120.0U/mL,1.75U/mL,0.85U/mL分别是不控制pH时的2.1、2.3、11.7和1.7倍.在不同pH下测定纤维素酶液各酶活,表明pH值显著影响纤维素酶各单酶酶活.在pH2.7时,β-葡萄糖苷酶酶活仅为pH4.8时酶活的4%;pH回调试验结果表明β-葡萄糖苷酶对pH敏感,并在催化功能上发生不可逆变化.对纤维素酶液添加分离得到的各单酶,当添加β-葡萄糖苷酶时最多可以提高FPA酶活20%.因此β-葡萄糖苷酶是影响综合酶活的关键酶.通过拉曼光谱检测出β-葡萄糖苷酶在pH5.0有活性状态下,酶蛋白主链结构主要为a-螺旋和无规则卷曲;在pH2.0没有活性状态下,酶蛋白主链结构的无规则卷曲发生较大变化,a-螺旋也受到一定影响.这说明pH对β-葡萄糖苷酶构象的改变是造成其活性变化的主要原因.