The nature and mode of action of the cellulolytic component C1 of Trichoderma koningii on native cellulose

The cellulolytic enzymes of Botryodiplodia theobromae Pat. Separation and characterization of cellulases and beta-glucosidases

1. Filtrates from cultures of different ages of Botryodiplodia theobromae Pat. were fractionated by gel filtration, ion-exchange chromatography and polyacrylamide-gel electrophoresis. 2. Five cellulases (C1, C2, C3, C4 and C5) were found, and their molecular weights, estimated by gel filtration, were 46000-48000 (C1), 30000-35000 (C2), 15000-18000 (C3), 10000-11000 (C4) and 4800-5500 (C5). 3. Cellulase C5 was absent from old culture filtrates. 4. Cellulase C1 had little or no activity on CM-cellulose (viscometric assay), but degraded cotton flock and Whatman cellulose powder to give cellobiose only. 5. The other components (C2-C5) produced cellobiose and smaller amounts of glucose and cellotriose from cellulosic substrates and were more active in lowering the viscosity of CM-cellulose. 6. The ratio of activities assayed by viscometry and by the release of reducing sugars from CM-cellulose increased with decrease in the molecular weights of cellulases C2-C5. 7. Cellobiose inhibited the activities of the cellulases, but glucose stimulated at low concentrations although it inhibited at high concentrations. 8. A high-molecular-weight beta-glucosidase (component B1, mol.wt. 350000-380000) predominated in filtrates from young cultures, but a low-molecular-weight enzyme (B4, mol.wt. 45000-47000) predominated in older filtrates. 9. Intermediate molecular species of beta-glucosidase (B2, mol.wt. 170000-180000; B3, mol.wt. 83000-87000) were also found. 10. Cellulases C2-C5 acted in synergism with C1, particularly in the presence of beta-glucosidase.

Studies on the mechanism of enzymatic hydrolysis of cellulosic substances

Most cellulosic substances contain appreciable amounts of cellulose and hemicellulose, which on enzymatic hydrolysis mainly yield a mixture of glucose, cellobiose, and xylose. In this paper, studies on the mechanisms of hydrolysis of bagasse (a complex native cellulosic waste left after extraction of juice from cane sugar) by the cellulase enzyme components are described in light of their adsorption characteristics. Simultaneous adsorption of exo- and endoglucanases on hydrolyzable cellulosics is the causative factor of the hydrolysis that follows immediately after. It supports the postulate of synergistic enzyme action proposed by Eriksson. Xylanase pretreatment enhanced the hydrolysis of bagasse owing to the creation of more accessible cellulosic regions that are readily acted upon by exo- and endoglucanases. The synergistic action of the purified exoglucanase, endoglucanase, and xylanse has been found to be most effective for hydrolysis of bagasse but not for pure cellulose. Significant quantities of glucose are produced in beta-glucosidase-free cellulase action on bagasse. Individual and combined action of the purified cellulase components on hydrolysis of native and delignified bagasse are discussed in respect to the release of sugars in the hydrolysate.

Purification and partial characterization of three extracellular cellulases from Cellulomonas sp

Three extracellular cellulases have been purified from cultures of Cellulomonas. One was found in solution in the cell-free supernatant and two others were found to be bound to the cellulose added as a carbon source. The free enzyme and one of the cellulose-bound enzymes bind to Sephadex. The two cellulose-bound enzymes are glycosylated. The three enzymes behave as endocellulases towards soluble carboxymethyl-cellulose and have little activity on cellulose powder.

The cellulase of Trichoderma koningii. Purification and properties of some endoglucanase components with special reference to their action on cellulose when acting alone and in synergism with the cellobiohydrolase

1. Four principal endoglucanase components of Trichoderma koningii cellulase were separated and purified by gel filtration on Sephadex G-75, ion-exchange chromatography on DEAE- and sulphoethyl-Sephadex and isoelectric focusing. 2. All four endoglucanases hydrolysed CM-cellulose, H3PO4-swollen cellulose, cellotetraose and cellopentaose, but differed in the rate and mode of attack. 3. Attack on cotton fibre by the endoglucanases was minimal, but resulted in changes that were manifested by an increased capacity for the uptake of alkali, and a decrease in tensile strength. 4. All four endoglucanases acted synergistically with the exoglucanase [cellobiohydrolase; Wood & McCrae (1972) Biochem. J. 128, 1183-1192] of T. koningii during the early stages of the breakdown of cotton fibre, but only two could produce extensive solubilization of cotton cellulose when acting in admixture with the exoglucanase component. 5. The mode of action of the enzymes is discussed in relation to these synergistic effects. It is suggested that the results are compatible with the interpretation that the 'crystalline' areas of cotton cellulose are hydrolysed only by those endoglucanases capable of forming of forming an enzyme-enzyme complex with the cellobiohydrolase on the surface of the cellulose chains.

Affinity chromatography of the cellulase system of Trichoderma koningii

A procedure involving affinity chromatography on cellulose was developed for separating enzymic components of the cellulase complex. Cellobiase, carboxymethylcellulase, component C2 and cellobiohydrolase are adsorbed with increasing tenacity, and released, as highly purified components, as the ionic strength of the eluent is decreased.

Cellulolytic activity of some soil fungi

The cellulolytic activity of some soil fungi isolated from soil and decomposing pieces of plant material was observed to depend upon the genera of fungi, the nature of substrate and the temperature. The cellulase produced in the presence of cellulose powder was active against CMC and vice versa.

Cellulase from Fusarium solani: purification and properties of the C1 component

The C1 component from Fusarium solani cellulase was purified extensively by molecular-sieve chromatography on Ultrogel AcA-54 and ion-exchange chromatography on DEAE-Sephadex. The purified component showed little capacity for hydrolysing highly ordered substrates (e.g., cotton fibre), but poorly ordered substrates (e.g., H3PO4-swollen cellulose), and the soluble cello-oligosaccharides cellotetraose and cellohexaose, were readily hydrolysed; cellobiose was the principal product in each case. Attack on O(-carboxymethyl)cellulose, a substrate widely used for measuring the activity of the randomly acting enzymes (Cx enzymes) of the cellulase complex, was minimal, and ceased after the removal of a few unsubstituted residues from the end of the chain. These observations, and the fact that the rate of change of degree of polymerisation of H3PO4-swollen cellulose was very slow compared with that effected by the randomly acting endoglucanases (Cx, CM-cellulases), indicate that C1 is a cellobiohydrolase. Fractionation by a variety of methods gave no evidence for the non-identity of the cellobiohydrolase and the component that acted in synergism with the randomly acting Cx enzyme when solubilizing cotton fibre.

Cellobiase from Trichoderma viride: purification, properties, kinetics, and mechanism

Three distinct cellobiase components were isolated from a commercial Trichoderma viride cellulase preparation by repeated chromatography on DEAE cellulose eluting by a salt gradient. The purified cellobiase preparations were evaluated for physical properties, kinetics, and mechanism. Results from this work include: 1) development of one step enzyme purification procedure using DEAE-cellulose; 2) isolation of three chromatographically distinct, yet kinetically similar, cellobiase fractions of molecular weight of approximately 76,000; 3) determination of kinetics which shows that cellobiase hydrolyzes cellobiose by a noncompetitive mechanism and that the product, glucose, inhibits the enzyme, and 4) development of an equation, based on the mechanism of cellobiase action, which accurately predicts the time course of cellobiose hydrolysis over an eightfold range of substrate concentration and conversions of up to 90%. Based on the data presented in the paper, it is shown that product inhibition of cellobiase significantly retards the rate of cellobiose hydrolysis.

Comparison of four purified extracellular 1,4-beta-D-glucan cellobiohydrolase enzymes from Trichoderma viride

Four electrophoretically distinct 1,4-beta-D-glucan cellobiohydrolase enzymes (exo-cellobiohydrolase, EC 3.2.1.91) from Trichoderma viride have been purified to homogeneity. Three enzymes (A, B, and C) were from a commercial T. viride preparation whereas the other (D) was from T. viride QM 9123 grown on cellulose in submerged culture. The enzymes were similar with respect to ultraviolet light absorption, amino acid and amino sugar composition, heat stability, molecular weight, specific activity, and carboxyterminal residues, indicating very nearly identical polypeptide portions. The enzymes also exhibited immunological cross-reactivity. The enzymes differed most in the content and composition of covalently bound neutral carbohydrate.

Structural characterization of a glycoprotein cellulase, 1,4-beta-D-glucan cellobiohydrolase C from Trichoderma viride

A glycoprotein enzyme, 1,4-beta-D-glucan cellobiohycrolase (EC 3.2.1.91) form C, was purified to electrophoretic homogeneity by a procedure which permitted isolation of gram quantities from a commercial Trichoderma viride culture filtrate preparation. Purified cellobiohydrolase C has an E1%/280 nm = 14.2 and degrades both microcrystalline and phosphoric acid-swollen cellulose to cellobiose. The cellobiohydrolase C contains 26.4, 4.8, 2.4 and 3.4 mol of mannose, glucose, galactose and glucosamine, respectively, per mol of enzyme (molecular weight, 48 400). Methylation analysis of cellobiohydrolase glycopeptides indicates an average carbohydrate chain length of two residues. Alkaline borohydride treatment of cellobiohydrolase C released neutral carbohydrate which is bound through an average of 16.7 O-glycosidic linkages to serine and threonine per molecule of enzyme. Glucosamine was not released from the protein by alkaline treatment. Analysis of alkaline borohydride-released carbohydrate by high pressure liquid chromatography demonstrated that an average enzyme molecule contains 8.8 mono-, 1.8 di-, 4.6 tri-, 1.2 tetra-, and 0.4 pentasaccharide chains. The linkages between the neutral monosaccharides are (1 leads to 6) as shown by gas chromatography - mass spectrometry of partially methylated residues. The (1 leads to 6) linkage is consistent with the stability of the linkages to alkaline conditions and the destruction of all neutral carbohydrate by periodate. Action of alpha-mannosidase indicates that some oligosaccharide chains contain alpha-mannose as the terminal residue.

Beta-glucosidase of Trichoderma: its biosynthesis and role in saccharification of cellulose

The extracellular beta-glucosidase of Trichoderma viride generally is present in low levels when the organism is cultured on cellulose because it is inactivated under the acid conditions which develop in the medium while the other enzymes of the cellulase complex are more stable. With the appropriate pH control, inactivation of beta-glucosidase is prevented and the activity of this enzyme increases during growth. In the saccharification of crystalline cellulose, or of cellulose at low concentrations, much of the glucose produced is the result of the cleavage of cellobiose by beta-glucosidase. However when high concentrations (10%) of pretreated cellulose are saccharified, significant quantities of glucose are produced by action of enzymes other than beta-glucosidase.