Purification and properties of a cellobiohydrolase from Penicillium pinophilum

Cellobiohydrolase II, isolated from the extracellular cellulase system of Penicillium pinophilum by chromatography on DEAE-Sephadex and DEAE-Sepharose followed by chromatofocusing, gave a single homogeneous band in SDS-gel electrophoresis and gel electrophoresis and gel electrofocusing. It had a molecular weight of 50,700 and of pI of 5.0, and was associated with 19% of carbohydrate. Cellobiose was the sole product of hydrolysis of the cellulosic materials, Avicel and H₃PO₄-swollen cellulose. No cross reaction was observed with antiserum prepared with another purified cellobiohydrolase (I) isolated from the same cellulase system. Cellobiohydrolase II showed no capacity for producing short fibres from filter paper. Avicel was hydrolysed extensively, but little or no hydrolysis of cotton fibre was apparent. However, cotton fibre was hydrolysed with a reconstituted mixture of the purified cellobiohydrolase II and the four major endo-(1→4)-β-d-glucanases isolated during fractionation. The action of cellobiohydrolase II on H₃PO₄-swollen cellulose was stimulated by high concentrations of cellobiose, but inhibited by high concentrations of d-glucose. Other notable inhibitors were Mn²⁺ and carbodi-imide. The properties of cellobiohydrolase II and the immunologically unrelated cellobiohydrolase I are compared.     

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 (C_x 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 (C_x, 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 C_x enzyme when solubilizing cotton fibre.     

Detection and characterization of the specific and nonspecific endoglucanases of Trichoderma reesei: Evidence demonstrating endoglucanase activity by cellobiohydrolase II

The cellulase enzyme system of Trichoderma reesei RUT C-30 has been separated by DEAE ion exchange chromatography into four fractions. Their specificity towards substituted cellulose and cellooligosaccharides was revealed by analytical IEF and activity stains. Fraction EGI (26% of the total protein) exhibited mainly endoglucanase activity on carboxymethylcellulose (CMC) whereas endoglucanases EGII and EGIII (15% of the total protein) showed high activity towards CMC as well as xylan, 4-methylumbelliferyl cellobioside [MeUmb(Glc)₂] and p-nitrophenyl lactoside (pNPL). A subfraction of EGI (pI 5.9) which has been described in the literature as a cellobiohydrolase (CBHII) was isolated by preparative isoelectric focusing, and was shown to have only 3 U CMCase activity per milligram. Turbidimetric measurements and phase contrast microscopy demonstrated differences between endoglucanase and cellobiohydrolase behaviour during the hydrolysis of purified cellulose (Solka Floc BW-40). Treatment of the purified cellulose with endoglucanases resulted in fibre breakdown into small particles. This was contrasted with no morphological change to the fibres when contacted with the cellobiohydrolase. By this technique it was revealed that the EGI subfraction (pI 5.9) behaves as an endoglucanase and not as a cellobiohydrolase. Incubation of this enzyme with acid-swollen cellulose resulted in cellotriose production, as it did with other endoglucanases which exhibited CMCase activities >; 100 U mg⁻¹. Cellotriose was not present during the hydrolysis of acid-swollen cellulose with the CBHI fraction.     

Solubilization of native and derived forms of cellulose by cell-free microbial enzymes

1. Cell-free enzymes from Myrothecium verrucaria and Trichoderma koningii hydrolyse native undegraded cellulose, as found in cotton fibres, in a random manner to short insoluble fibres and to minor amounts of soluble products. 2. Enzyme preparations from M. verrucaria fail to attack the short fibres whereas preparations from T. koningii solubilize them completely to sugars at an optimum pH4.2-4.6. 3. The mode of hydrolysis of cotton cellulose by preparations from T. koningii involves from the earliest stages the formation of reducing sugars, followed closely by the appearance of short fibres, until the insoluble and soluble products each constitute about 40-50% of the weight of the initial substrate. After this stage the quantity of sugars increases at the expense of the insoluble short fibres. 4. Depending upon the method of preparation, derived forms of cellulose may be hydrolysed more slowly, much more rapidly, or at the same rate as cotton fibres by enzyme preparations from T. koningii.     

The mechanism of fungal cellulase action. Synergism between enzyme components of Penicillium pinophilum cellulase in solubilizing hydrogen bond-ordered cellulose.

Studies on reconstituted mixtures of extensively purified cellobiohydrolases I and II and the five major endoglucanases of the fungus Penicillium pinophilum have provided some new information on the mechanism by which crystalline cellulose in the form of the cotton fibre is rendered soluble. It was observed that there was little or no synergistic activity either between purified cellobiohydrolases I and II, or, contrary to previous findings, between the individual cellobiohydrolases and the endoglucanases. Cotton fibre was degraded to a significant degree only when three enzymes were present in the reconstituted enzyme mixture: these were cellobiohydrolases I and II and some specific endoglucanases. The optimum ratio of the cellobiohydrolases was 1:1. Only a trace of endoglucanase activity was required to make the mixture of cellobiohydrolases I and II effective. The addition of cellobiohydrolases I and II individually to endoglucanases from other cellulolytic fungi resulted in little synergistic activity; however, a mixture of endoglucanases and both cellobiohydrolases was effective. It is suggested that current concepts of the mechanism of cellulase action may be the result of incompletely resolved complexes between cellobiohydrolase and endoglucanase activities. It was found that such complexes in filtrates of P. pinophilium or Trichoderma reesei were easily resolved using affinity chromatography on a column of p-aminobenzyl-1-thio-beta-D-cellobioside.     

Saccharification of native and degraded cotton cellulose and commercial microcrystalline cellulose by Trichoderma viride cellobiohydrolase I

The degree of polymerization of samples of acid degraded cotton cellulose has no appreciable influence on the saccharification by cellobiohydrolase I from Trichoderma viride. The increase in the number of cellulose molecule ends, achieved by a 30-fold decrease in molecular weight, does not produce the effect which could be expected for a pure end-wise mode of action of this exoglucanase. Microcrystalline celluloses saccharified by the same enzyme yield considerably more reducing sugars than cotton cellulose, either with a similar degree of polymerization or one of about 7000. It appears, therefore, that the difference in the susceptibility of the commercial substrates is not a consequence of their low degree of polymerization.     

The cellulase of Penicillium pinophilum. Synergism between enzyme components in solubilizing cellulose with special reference to the involvement of two immunologically distinct cellobiohydrolases.

Two immunologically unrelated cellobiohydrolases (I and II), isolated from the extracellular cellulase system elaborated by the fungus Penicillum pinophilum, acted in synergism to solubilize the microcrystalline cellulose Avicel; the ratio of the two enzymes for maximum rate of attack was approx. 1:1. A hypothesis to explain the phenomenon of synergism between two endwise-acting cellobiohydrolases is presented. It is suggested that the cellobiohydrolases may be two stereospecific enzymes concerned with the hydrolysis of the two different configurations of non-reducing end groups that would exist in cellulose. Only one type of cellobiohydrolase has been isolated so far from the cellulases of the fungi Fusarium solani and Trichoderma koningii. Only cellobiohydrolase II of P. pinophilum acted synergistically with the cellobiohydrolase of the fungi T. koningii or F. solani to solubilize Avicel. Cellobiohydrolase II showed no capacity for co-operating with the endo-1,4-beta-glucanase of T. koningii or F. solani to solubilize crystalline cellulose, but cellobiohydrolase I did. These results are discussed in the context of the hypothesis presented.     

Purification and characterization of endoglucanase and exoglucanase components from Trichoderma viride

Major cellulase components—four endoglucanases (Endo I, II, III and IV) and one exoglucanase (Exo II)—were isolated from a commercial cellulase preparation derived from Trichoderma viride by a series of chromatographic procedures. The average molecular weights were determined by SDS-polyacrylamide gel electrophoresis. Endos I, III and IV, with M_rs of 52,000, 42,000 and 38,000, respectively, exhibited a more random hydrolytic mode on carboxymethylcellulose (CMC) than Endo II, which has an M_r of 60,000. Endo II showed low activity towards CMC, but out of the four purified endoglucanases this enzyme had the highest specific activity against Avicel. In the hydrolysis of H₃PO₄-swollen cellulose by Endos I, III and IV, cellobiose was the major product, but equimolar amounts of glucose and cellobiose were formed by Endo II. Exo II, with an M_r of 62,000, released cellobiose as the main product in the hydrolysis of H₃PO₄-swollen cellulose, but glucose was negligible. The combination of Endo I, II, III or IV with Exo II resulted in a synergistic effect in the degradation of Avicel at various combination ratios of these enzymes; the specific optimum ratio of endoglucanase to exoglucanase was largely dependent upon the random hydrolytic mode of the endoglucanase. On the other hand, adsorption of cellulase components was found apparently to obey the Langmuir isotherm, and the thermodynamic parameter (ΔH) was calculated from the adsorption equilibrium constant (K). The enthalpies of adsorption of the endoglucanases were in the range of −2.6–−7.2 KJmol⁻¹, much smaller than that of Exo II (−19.4 KJmol⁻¹). This suggest that Exo II shows stronger preferential adsorption than endoglucanases, and that the enthalpy of adsorption will be effective in distinguishing endoglucanase from exoglucanase.     

Retinol and retinal metabolism. Relationship to the state of differentiation of cultured human keratinocytes.

The modes of action of the five major endo-(1----4)-beta-D-glucanases (I, II, III, IV and V) purified from Penicillium pinophilum cellulase were compared by h.p.l.c. analysis, with normal, 1-3H-labelled and reduced cello-oligosaccharides and 4-methylumbelliferyl glycosides as substrates. Significant differences were observed in the preferred site of cleavage even when substrates with the same number of glycosidic bonds were compared. Thus, although endoglucanase I was unable to attack normal cello-oligosaccharides shorter than degree of polymerization 6, it hydrolysed reduced cellopentaose to yield cellotriose and cellobi-itol, and it produced cellotriose and 4-methylumbelliferyl glucoside from 4-methylumbelliferyl cellotetraoside. Endoglucanase IV hydrolysed [1-3H]cellotriose but did not attack either cellotri-itol or 4-methylumbelliferyl cellobioside. These and other anomalous results indicated clearly that modification of the reducing glycosyl residue on the cello-oligosaccharides induces in an apparent change in the mode of action of the endoglucanases. It is suggested that, although cello-oligosaccharide derivatives are useful for differentiating and classifying endoglucanases, conclusions on the mechanism of cellulase action resulting from these measurements should be treated cautiously. Unequivocal information on the mode of endoglucanase action on cello-oligosaccharides was obtained with radiolabelled cello-oligosaccharides of degree of polymerization 3 to 5. Indications that transglycosylation was a property of the endoglucanases were particularly evident with the 4-methylumbelliferyl cello-oligosaccharides. Turnover numbers for hydrolysis of the umbelliferyl cello-oligosaccharides were calculated, and these, along with the other analytical data collected on the products of hydrolysis of the normal, reduced and radiolabelled cello-oligosaccharides, suggested that the various endoglucanases had different roles to play in the overall hydrolysis of cellulose to sugars small enough to be transported through the cell membrane.     

Degradation of crystalline cellulose by the brown-rot basidiomycete Fomitopsis palustris

This study demonstrated that the brown rot basidiomycete Fomitopsis palustris was able to degrade crystalline cellulose (Avicel). This fungus could also produce the three major cellulases (exoglucanases, endoglucanases, and beta-glucosidase) when the cells were grown on 2.0% Avicel. Avicel degraded by F. palustris showed a decrease in relative crystallinity from 83% to 78.5% after 14 days of incubation. The characterization study indicated that optimum pH was 4.5 and optimum temperature was 70 degrees C for exoglucanase (cellobiohydrolase) activity. Hydrolysis of Avicel by the crude enzyme from F. palustris yielded 1.6 mg/ml of glucose after 43 h, which corresponded to a cellulose conversion degree of 3.2%. Therefore, this study revealed for the first time that the brown rot basidiomycete F. palustris produces cellulases capable of yielding soluble sugars from crystalline cellulose.     

Comparison of a fungal (family I) and bacterial (family II) cellulose-binding domain.

A family II cellulose-binding domain (CBD) of an exoglucanase/xylanase (Cex) from the bacterium Cellulomonas fimi was replaced with the family I CBD of cellobiohydrolase I (CbhI) from the fungus Trichoderma reesei. Expression of the hybrid gene in Escherichia coli yielded up to 50 mg of the hybrid protein, CexCBDCbhI, per liter of culture supernatant. The hybrid was purified to homogeneity by affinity chromatography on cellulose. The relative association constants (Kr) for the binding of Cex, CexCBDCbhI, the catalytic domain of Cex (p33), and CbhI to bacterial microcrystalline cellulose (BMCC) were 14.9, 7.8, 0.8, and 10.6 liters g-1, respectively. Cex and CexCBDCbhI had similar substrate specificities and similar activities on crystalline and amorphous cellulose. Both released predominantly cellobiose and cellotriose from amorphous cellulose. CexCBDCbhI was two to three times less active than Cex on BMCC, but significantly more active than Cex on soluble cellulose and on xylan. Unlike Cex, the hybrid protein neither bound to alpha-chitin nor released small particles from dewaxed cotton fibers.     

Mechanism of substrate inhibition in cellulose synergistic degradation.

A comprehensive experimental study of substrate inhibition in cellulose hydrolysis based on a well defined system is presented. The hydrolysis of bacterial cellulose by synergistically operating binary mixtures of cellobiohydrolase I from Trichoderma reesei and five different endoglucanases as well as their catalytic domains displays a characteristic substrate inhibition. This inhibition phenomenon is shown to require the two-domain structure of an intact cellobiohydrolase. The experimental data were in accordance with a mechanism where cellobiohydrolases previously bound to the cellulose by means of their cellulose binding domains are able to find chain ends by lateral diffusion. An increased substrate concentration at a fixed enzyme load will also increase the average diffusion distance/time needed for cellobiohydrolases to reach new chain ends created by endoglucanases, resulting in an apparent substrate inhibition of the synergistic action. The connection between the binding properties and the substrate inhibition is encouraging with respect to molecular engineering of the binding domain for optimal performance in biotechnological processes.     

Differential regulation of synthesis of multiple forms of specific endoglucanases by Trichoderma reesei QM9414.

A method consisting of sodium dodecyl sulfate-polyacrylamide gel electrophoresis and subsequent detection of endoglucanases by blotting with a polyclonal antibody against endoglucanase I was used to investigate the effect of induction and carbon catabolite derepression on the synthesis of multiple forms of endoglucanase I by Trichoderma reesei. Five forms appeared upon growth on cellulose, whereas four and only two appeared upon growth on lactose (carbon catabolite derepression) and induction by sophorose in a resting cell system, respectively. All endoglucanases detected resembled endoglucanase I in their specificity, since they exhibited no activity toward xylan or paranitrophenyl-beta-D-lactobioside. A small (25-kilodalton) endoglucanase only appeared during growth on cellulose. None of the multiple forms arose by postsecretional modification. The results indicate that sophorose may not be the only compound mediating cellulose induction of the specific endoglucanases in T. reesei.     

The purification and properties of the C1 component of Trichoderma koningii cellulase

1. The C(1) component that was isolated from a Trichoderma koningii cellulase preparation (Wood, 1968) by chromatography on DEAE-Sephadex with a salt gradient was still associated with a trace of CM-cellulase activity (determined by reducing-sugar and viscometric methods). 2. Further chromatography on DEAE-Sephadex, with a pH gradient instead of a salt gradient, provided a C(1) component that could still produce reducing sugars from a solution of CM-cellulose (to a very limited extent), but which could no longer decrease the viscosity (i.e. under the assay conditions employed). 3. No evidence for the non-identity of C(1) component and the trace of CM-cellulase activity could be found when electrofocusing was done in a stabilized pH gradient covering three pH units (pH3-6) or, alternatively, only 0.5 pH unit (pH3.72-4.25). 4. The two protein peaks that were separated by electrofocusing in carrier ampholytes covering only 0.5 pH unit (isoelectric pH values of 3.80 and 3.95) were shown to be isoenzymes of the C(1) component: they differed in the extent to which they were associated with carbohydrate (9% and 33%). 5. The purified C(1) component had little ability to attack CM-cellulose or highly ordered forms of cellulose, but degraded phosphoric acid-swollen cellulose readily: cellobiose was the principal product of the hydrolysis (97%). 6. Dewaxed cotton fibre was degraded to the extent of 15% when exposed to high concentrations of C(1) component over a prolonged period: cellobiose was again the principal sugar present in the supernatant (96%). 7. Cellotetraose and cellohexaose were hydrolysed almost exclusively to cellobiose. 8. Evidence indicates that the C(1) component is a beta-1,4-glucan cellobiosylhydrolase.     

DNA sequence of a Fibrobacter succinogenes mixed-linkage beta-glucanase (1,3-1,4-beta-D-glucan 4-glucanohydrolase) gene.

The DNA sequence of a mixed-linkage beta-glucanase (1,3-1,4-beta-D-glucan 4-glucanohydrolase [EC 3.2.1.73]) gene from Fibrobacter succinogenes cloned in Escherichia coli was determined. The general features of this gene are very similar to the consensus features for other gram-negative bacterial genes. The gene product was processed for export in E. coli. There is a high level of sequence homology between the structure of this glucanase and the structure of a mixed-linkage beta-glucanase from Bacillus subtilis. The nonhomologous region of the amino acid sequence includes a serine-rich region containing five repeats of the sequence Pro-Xxx-Ser-Ser-Ser-Ser-(Ala or Val) which may be functionally related to the serine-rich region observed in Pseudomonas fluorescens cellulase and the serine- and/or threonine-rich regions observed in Cellulomonas fimi endoglucanase and exoglucanase, in Clostridium thermocellum endoglucanases A and B, and in Trichoderma reesei cellobiohydrolase I, cellobiohydrolase II, and endoglucanase I.     

Cellulase Activity of Leishmania major in the Sandfly Vector and in Culture

ABSTRACT. The secretion of cellulose-degrading enzymes by Leishmania promastigotes in culture and in the sandfly vector was demonstrated. Two types of activity of cellulase enzyme-complexes were measured: endoglucanases, which randomly cleave cellulose chains and cellobioydrolases, which remove cellobiose from the nonreducing end of the molecule. The assays demonstrated that enzymes with these activities were secreted into the culture medium by Leishmania major, L. donovani , and L. braziliensis . These activities were also found in cultures of Sauroleishmania agamae, Leptomonas seymouri, Herpetomonas muscarum, Crithidia fasciculata and Trypanosoma brucei brucei that had a relatively low endoglucanase activity. Both endoglucanase and cellobiohydrolase activities were found in the gut of L. major-infected Phlebotomus papatasi , while gut preparations of uninfected sandflies had only cellobiohydrolase activity. The similar growth of L. major parasites in medium supplemented with either cellulose or glucose suggests these parasites can utilize cellulose.     

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.     

The formation of short fibres from native cellulose by components of Trichoderma koningii cellulase

Cellulolytic enzyme components of culture filtrates of Trichoderma koningii were fractionated on ionic and non-ionic forms of Sephadex and on cellulose powder (Whatman) and examined for their ability to hydrolyse soluble carboxymethyl-cellulose, and to saccharify, solubilize and form short fibres from native undegraded cellulose of the type found in cotton. DEAE-Sephadex provided two CM-cellulase components and a C(1) component; the C(1) component acted weakly and solely on cotton, forming soluble products but not short fibres. The ability to form short fibres was confined almost wholly to one of the CM-cellulase components which completely degraded cotton, minimally to soluble products and extensively to short fibres. The latter action was unaffected by the presence of the other two components. The two CM-cellulase components solubilized cellulose synergistically whereas the short-fibre-forming component and C(1) component were inhibitory.