Response of Cellulase Activity in pH-Controlled Cultures of the Filamentous Fungus <Emphasis Type="Italic">Acremonium cellulolyticus</Emphasis>

Cellulase production was investigated in pH-controlled cultures of Acremonium cellulolyticus. The response to culture pH was investigated for three cellulolytic enzymes, carbomethyl cellulase (CMCase), avicelase, and β-glucosidase. Avicelase and β-glucosidase showed similar profiles, with maximum activity in cultures at pH 5.5–6. The CMCase activity was highest in a pH 4 culture. At an acidic pH, the ratios of CMCase and avicelase activity to cellulase activity defined by filter paper unit were high, but at a neutral pH, the β-glucosidase ratio was high. The pH 6.0 culture showed the highest cellulase activity within the range of pH 3.5–6.5 cultures. The saccharification activity from A. cellulolyticus was compared to those of the cellulolytic enzymes from other species. The A. cellulolyticus culture broth had a saccharification yield comparable to those of the Trichoderma enzymes GC220 and Cellulosin T2, under conditions with the same cellulase activity. The saccharification yields from Solka floc, Avicel, and waste paper, measured as the percent of released reducing sugar to dried substrate, were greater than 80% after 96 h of reaction. The yields were 16% from carboxymethylcellulose and 26% from wood chip refiner. Thus, the A. cellulolyticus enzymes were suitable for converting cellulolytic biomass to reducing sugars for biomass ethanol production. This study is a step toward the establishment of an efficient system to reutilize cellulolytic biomass.     

Xylanase and cellulase production byAspergillus fumigatus

When grown on a purified cellulose such as CF11 cellulose,Aspergillus fumigatus produces mainly exoglucanase (Avicelase) and endoglucanase (CMCase) with small amounts of Β-glucosidase and xylanase. In such cultures, the pH drops to 3–3.5 after 2 d incubation, which may account for the low levels of Β-glucosidase. The amounts of extracellular enzymes produced are larger when the organism is grown on hay or straw than when grown on CF11 cellulose. In particular, CMCase levels increase approximately seven times and xylanase levels increase 40–50 times. In such cultures the pH remains fairly constant at 6–7 over the 10-d incubation period used and so Β-glucosidase levels are also increased. Extraction of the hay or straw substrate with ethanol had little effect on enzyme production and so there appears to be no soluble material present that influences enzyme production. The organism produced elevated levels of CMCase and xylanase on barley straw, oat straw, and wheat straw, there being little difference between the varieties of each tested. However, grasses dried at elevated temperatures (260–500‡C) gave enzyme levels similar to CF11 cellulose. Similarly, chemical delignification of hay or straw gave enzyme levels similar to CF11 cellulose. Thus, both these treatments must lead to degradation of the hemicellulose present in the substrate. A. fumigatus was able to grow on a number of laboratory prepared and commercially available xylans (hay, barley straw, oat straw, and larch) as a pelletted mycelium. In all cases xylanase levels were increased 10–30 times over CF11 cellulose as substrate, but CMCase levels were similar to those with CF11 cellulose as substrate. Β-Glucosidase in most cases was not detectable, probably because the pH fell to 3–3.5 during incubation. Thus it appears that cellulase and xylanase can be independently induced in this organism. The optimum incubation time at 37‡C for xylanase production was 4–7 d and the optimum concentration of hay as substrate was 4–5%, even though this produces a very thick slurry that does not shake well.     

Production of extracellular xylanases byPenicillium janthinellum

Xylanase production byPenicillium janthinellum using 10–100 mM of 2,2-dimethylsuccinate (DMS) buffer, in a range of pH 4.5-6.0 was studied. The enzyme activity was enhanced using oat xylan as the carbon source. Under these conditions a culture produced 1.14 Μmol/ min (11.4 U/mL or 84.4 U/mg) of Β-xylanase after 5 d of growth in a 10-mM buffer solution at pH 4.5. Protease was absent in the DMS buffer except when 100 mM phosphate buffer at pH 6.0 was used (4 U/mL). Β-Xylosidase was only found at a pH of 4.5 in all the buffer concentrations. At a 50 mM DMS buffer concentration at pH 4.5 Β- xylanases were induced by both oat and birch xylans, having a greater effect with oat spelt xylans. Electrophoretic analyses showed that the birchwood xylan induction exhibited different proteins profiles. No Β-xylosidase or Β- glucosidase was induced until d 5. The Β-xylanases were rapidly inactivated at 50‡C, however, birch xylanase appeared to be more stable than oat xylanase. Using oat xylan as an inductor, theΒ-xylosidase andΒ-glucosidase were 85 and 91 U/L, respectively, on d 7. The xylanase produced by induction from sugar cane bagasse hydrolyzate was used for pulp biobleaching. A 20% decrease on the Kappa value in Kraft pulp using the culture extract was obtained. These selective growth conditions led us to modulate the xylanase production for pulp delignification.     

Synthesis of lsopropyl-1-thio-Β-D-glucopyranoside (IPTGlc), an inducer ofaspergillus niger b1 Β-glucosidase production

Production of Β-glucosidase inAspergillus niger Bl is subjected to catabolic repression by glucose.Aspergillus niger Bl grown on bran as a carbon source secreted Β-glucosidase. The maximum level of the enzyme was reached after 7 d of fermentation. Addition of 1% glucose to the medium suppressed Β-glucosidase production to undetectable levels. In this study, the organic synthesis of a potential inducer of Β-glucosidase production by A.niger Bl’s reported. Isopropyl-1-thio-Β-D-glucopyranoside (IPTGlc) was synthesized using a two-step organic synthesis protocol. The H-NMR data agreed with those reported previously for the galactoside analog. When IPTGlc was added 24 h after inoculation at a final concentration of 0.4 mM, similar levels of Β-glucosidase were reached 3 to 4 d earlier as compared to fermentation without IPTGlc induction. In practice, this may translate to a more efficient method of producing Β-glucosidase from this fungus.     

Hydrolysis of Ammonia-pretreated Sugar Cane Bagasse with Cellulase, β-Glucosidase, and Hemicellulase Preparations

Sugar cane bagasse consists of hemicellulose (24%) and cellulose (38%), and bioconversion of both fractions to ethanol should be considered for a viable process. We have evaluated the hydrolysis of pretreated bagasse with combinations of cellulase, β-glucosidase, and hemicellulase. Ground bagasse was pretreated either by the AFEX process (2NH₃: 1 biomass, 100 °C, 30 min) or with NH₄OH (0.5 g NH₄OH of a 28% [v/v] per gram dry biomass; 160 °C, 60 min), and composition analysis showed that the glucan and xylan fractions remained largely intact. The enzyme activities of four commercial xylanase preparations and supernatants of four laboratory-grown fungi were determined and evaluated for their ability to boost xylan hydrolysis when added to cellulase and β-glucosidase (10 filter paper units [FPU]: 20 cellobiase units [CBU]/g glucan). At 1% glucan loading, the commercial enzyme preparations (added at 10% or 50% levels of total protein in the enzyme preparations) boosted xylan and glucan hydrolysis in both pretreated bagasse samples. Xylanase addition at 10% protein level also improved hydrolysis of xylan and glucan fractions up to 10% glucan loading (28% solids loading). Significant xylanase activity in enzyme cocktails appears to be required for improving hydrolysis of both glucan and xylan fractions of ammonia pretreated sugar cane bagasse.     

Cellulolytic enzymes produced by the edible mushroom,Pleurotus sajor-caju

Pleurotus sajor-caju grows efficiently and degrades all the components present in lignocellulosic residues. Production of cellulase and xylanase enzymes in submerged culture and during solid state cultivation has been studied. An initial pH of 5.0 was found to be optimal for the production of cellulase in shake flasks; this was attained in about 6–8 d in a medium containing either cellulose or rice straw as the sole source of carbon. On the cellulose medium, the maximum filter paper activity attained was 0.15 IU/mL in 7 d whereas the endoglycanase activity of 1.0 IU/mL, xylanase activity of 1.55 IU/mL, and Β-glucosidase activity of 0.57 IU/mL were acheived after 9 d fermentation. The reducing sugars were absent in the culture medium. The cellulases (filter paper activity and endoglucanases) were most active at pH 5.0 and 45‡C. Xylanase had maximum activity at pH 4.8 and 45‡C, and Β-glucosidase at pH 5.5 and 40‡C. In shake cultures,P. sajor-caju produced dispersed suspension of short mycelial threads and various sizes of pellets. The profile and extent of enzyme biosynthesis during submerged cultivation on rice straw was found to be of the same nature as obtained on cellulose. During solid state cultivation ofP. sajor-caju on rice straw beds for 36 d, the elaboration of enzyme activities did not appear to follow any definite pattern. However, filter paper activity, which is representative of cellulase action in hydrolyzing cellulose, remained more or less constant during the period of about the first 20 d of cultivation after the appearance of fruit bodies on the surface of rice straw beds. All the activities attained their minimum values after 23 d of cultivation, during which approximately 1 kg of fresh fruit bodies had been harvested. The total fruit bodies harvested till 36th days were approx. 1.1 kg. ThroughT. sajor-caju elaborates cellulase and xylanse extracellularly, the activity values were not as high as those of other cellulase producers such asTrichoderma reesei.     

Production of cellulase/β-glucosidase by the mixed fungi culture of Trichoderma reesei and Aspergillus phoenicis on dairy manure

A cellulase production process was developed by growing the fungi Trichoderma reesei and Aspergillus phoenicis on dairy manure. T. reesei produced a high total cellulase titer (1.7 filter paper units [FPU]/mL, filter paper activity) in medium containing 10 g/L of manure (dry basis [w/w]), 2 g/L KH₂PO₄, 2 mL/L of Tween-80, and 2mg/L of CoCl₂. However, β-glucosidase activity in the T. reesei-enzyme system was very low. T. reesei was then cocultured with A. phoenicis to enhance the β-glucosidase level. The mixed culture resulted in a relatively high level of total cellulase (1.54 FPU/mL) and β-glucosidase (0.64 IU/mL). The ratio of β-glucosidase activity to filter paper activity was 0.41, suitable for hydrolyzing manure cellulose. The crude enzyme broth from the mixed culture was used for hydrolyzing the manure cellulose, and the produced glucose was significantly (p<0.01) higher than levels obtained by using the commercial enzyme or the enzyme broth of the pure culture T. reesei.     

Highly Thermostable Xylanase of the Thermophilic Fungus Talaromyces thermophilus: Purification and Characterization

A thermostable xylanase from a newly isolated thermophilic fungus Talaromyces thermophilus was purified and characterized. The enzyme was purified to homogeneity by ammonium sulfate precipitation, diethylaminoethyl cellulose anion exchange chromatography, P-100 gel filtration, and Mono Q chromatography with a 23-fold increase in specific activity and 17.5% recovery. The molecular weight of the xylanase was estimated to be 25kDa by sodium dodecyl sulfate–polyacrylamide gel electrophoresis and gel filtration. The enzyme was highly active over a wide range of pH from 4.0 to 10.0. The relative activities at pH5.0, 9.0, and 10.0 were about 80%, 85.0%, and 60% of that at pH7.5, respectively. The optimum temperature of the purified enzyme was 75°C. The enzyme showed high thermal stability at 50°C (7days) and the half-life of the xylanase at 100°C was 60min. The enzyme was free from cellulase activity. K _m and V _max values at 50°C of the purified enzyme for birchwood xylan were 22.51mg/ml and 1.235μmol min⁻¹ mg⁻¹, respectively. The enzyme was activated by Ag⁺, Co²⁺, and Cu²⁺; on the other hand, Hg²⁺, Ba²⁺, and Mn²⁺ inhibited the enzyme. The present study is among the first works to examine and describe a secreted, cellulase-free, and highly thermostable xylanase from the T. thermophilus fungus whose application as a pre-bleaching aid is of apparent importance for pulp and paper industries.     

Molecular cloning and expression of an endo-β-1,4-d-glucanase I (avicelase I) gene from Bacillus cellulyticus K-12 and characterization of the recombinant enzyme

Bacillus cellulyticus K-12 Avicelase (Avicelase I; EC 3.2.1.4) gene (ace A) has been cloned in Escherichia coli by using the vector pT7T3U19 and HindIII-HindIII libraries of the chromosomal inserts. The libraries were screened for the expression of avicelase by monitoring the immunoreaction of the antiavicelase (immunoscreening). Positive clones (Ac-3, Ac-5, and Ac-7) contained the identical 3.5-kb HindIII fragment as determined by restriction mapping and Southern hybridization, and expressed avicelase efficiently and constitutively using its own promoter in the heterologous host. From the immunoblotting analysis, a polypeptide that showed a carboxymethylcellulase (CMCase) activity with an M _r , of 64,000 was detected. The recombinant endo 1,4-β- _d -glucanase I was purified to homogeneity from an intracellular fraction of E. coli by DEAE-Toyopearl M650, Phenyl Toyoperal M650, and TSK gel HW50S chromatography. The enzyme had a monomeric structure, its relative molecular mass being 65 kDa by gel filtration and 64 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The pI was 5.3 and the optimal pH was 4.6, and the enzyme was stable at pH 4.0–10.5. The enzyme had a temperature optimum of 50°C and was stable at 55°C for 48 h, and retained approx 20% of its activity after 30 min at 70°C. It showed high activity toward carboxymethylcellulose (CMC) as well as p-nitrophenyl-β-d-cellobioside, 4-methylumbelliferyl cellobioside, Avicel, filter paper, and some cellooligosaccharides. K _m values for CMC and Avicel were 7.6 and 85.2 mg/mL, respectively, whereas V _max values were 201 and 9.2 μmol · min⁻¹ · mg⁻¹, respectively. Cellotetraose (G4) was preferentially cleaved into cellobiose (G2) and cellopentaose (G5) was cleaved into G2 + cellotriose (G3), whereas cellohexaose (G6) was cleaved into G4 + G2 and, to a lesser extent, into G3 + G3. G3 was not cleaved at all. G2 was the main product of Avicel hydrolysis. G2 inhibited whereas Mg⁺⁺ stimulated the activity of CMCase and Avicelase. Hydrolysis of CMC took place with a rapid decrease in viscosity but a slow liberation of reducing sugars. Based on these results, it appeared that the cellulase should be regarded as endo type, although it hydrolyzed Avicel.     

Detection of major xylanase-containing cellulose-binding domain from Penicillium verruculosum by combination of chromatofocusing and limited proteolysis

Adsorption on microcrystalline cell ulose of enzyme components of cellulase complex from Penicillium verruculosum was studied by chromatofocusing on a Mono P column. The most strongly adsorbed and major component was identified as xylanase (XYN) with MW 65 k Da and pl 4.5. The high adsorption degree of XYN on cellulose indicated the possible presence of a cellulose-binding domain in the molecular sturcture. Limited proteolysis of XYN with papain was carried out. Kinetics of proteolysis was monitored by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis and measuring activities toward insoluble xylan and 4-methylumbelliferyl-β-d-lactoside (MUF-LAC). During the proteolysis, formation of two polypeptides with MW 51 and 14k Da was observed. No loss of activity toward thesolu blesubstrate was observed, wherease the activity toward xylan decreased rapidly. Adsorption distribution coefficient (K _d) of the core protein separated by gel-filtration was found to be 15 times lower than the K _d for the initial nondigested XYN (0.02 and 0.29 L/g, respectively). The activity of core protein toward insoluble xylan was close to zero, whereas the activity toward MUF-LAC was close to that exhibited by the original enzyme. The results presented indicate a bifunctional organization of XYN, where one domain acts as a binding anchor for insoluble substrates and the other, localized in the core protein, contains the active site.     

Horticultural Waste as the Substrate for Cellulase and Hemicellulase Production by Trichoderma reesei Under Solid-State Fermentation

Horticultural waste in wood chips form collected from a landscape company in Singapore was utilized as the substrate for the production of cellulase and hemicellulase under solid-state fermentation by Trichoderma reesei RUT-C30. The effects of substrate pretreatment methods, substrate particle size, incubation temperature and time, initial medium pH value, and moisture content on cellulase and hemicellulase production were investigated. Enzyme complex was obtained at the optimal conditions. This enzyme mixture contained FPase (15.0 U/g substrate dry matter, SDM), CMCase (90.5 U/g SDM), β-glucosidase (61.6 U/g SDM), xylanase (52.1 U/g SDM), and β-xylosidase (10.4 U/g SDM). The soluble protein concentration in the enzyme complex was 26.1 mg/g SDM. The potential of the crude enzyme complex produced was demonstrated by the hydrolysis of wood chips, wood dust, palm oil fiber, and waste newspaper. The performance of the crude enzyme complex was better than the commercial enzyme blend.     

Semi-solid-state fermentation of Eicchornia crassipes biomass as lignocellulosic biopolymer for cellulase and β-glucosidase production by cocultivation of Aspergillus niger RK3 and Trichoderma reesei MTCC164

An aquatic weed biomass, Eicchornia crassipes, present in abundance and leading to a threatening level of water pollution was used as substrate for cellulase and β-glucosidase production using wild-type strain Aspergillus niger RK3 that was isolated from decomposing substrate. Alkali treatment of the biomass (10%) resulted in a 60–66% increase in endoglucanase, exoglucanase, and β-glucosidase production by the A. niger RK3 strain in semi-solid-state fermentation. Similarly, the alkali-treated biomass led to a 45–54% increase in endo- and exoglucanase and a higher (98%) increase in β-glucosidase production by Trichoderma reesei MTCC164 under similar conditions. However, the cocultivation of A. niger RK3 and T. reesei MTCC164 at a ratio of 3:1 showed a 20–24% increase in endo- and exoglucanase activities and about a 13% increase in the β-glucosidase activity over the maximum enzymatic activities observed under single culture conditions. Multistep physical (ultraviolet) and chemical (N-methyl-N′-nitrosoguanidine, sodium azide, colchicine) mutagenesis of the A. niger RK3 strain resulted in a highly cellulolytic mutant, UNSC-442, having an increase of 136, 138, and 96% in endoglucanase, exoglucanase, and β-glucosidase, activity, respectively. The cocultivation of mutant UNSC-442 along with T. reesei MTCC164 (at a ratio of 3:1) showed a further 10–11% increase in endo- and exoglucanase activities and a 29% increase in β-glucosidase activity in semi-solid-state fermentation.     

Relatively High-Substrate Consistency Hydrolysis of Steam-Pretreated Sweet Sorghum Bagasse at Relatively Low Cellulase Loading

Sweet sorghum bagasse (SSB) was steam pretreated in the conditions of 190 °C for 5 min to assess its amenability to the pretreatment and enzymatic hydrolysis. Results showed that pretreatment conditions were robust enough to pretreat SSB with maximum of 87% glucan and 72% xylan recovery. Subsequent enzymatic hydrolysis showed that the pretreated SSB at 2% substrate consistency resulted in maximum of 70% glucan-glucose conversion. Increasing substrate consistency from 2% to 16% led to a significant reduction in glucan conversion. However, the decrease ratio of glucan-glucose conversion was the minimum when the consistency increased from 2% to 12%. When the pretreated SSB consistency of 12% was applied for hydrolysis, increase in cellulase loading from 7.5 up to 20 filter paper units (FPU)/g glucan resulted only in 14% increase in glucan-glucose conversion compared to 20% increase with cellulase loading varying from 2.5 to 7.5 FPU/g glucan. More than 10 cellobiase units (CBU)/g glucan β-glucosidase supplementation had no noticeable improvement on glucan-glucose conversion. Additionally, supplementation of xylanase was found to significantly increase glucan-glucose conversion from 50% to 80% with the substrate consistency of 12%, when the cellulase and β-glucosidase loadings were at relatively low enzyme loadings (7.5 FPU/g and 10 CBU/g glucan). It appeared that residual xylan played a critical role in hindering the ease of hydrolysis of SSB. A proper xylanase addition was suggested to achieve a high hydrolysis yield at relatively high substrate consistency with relatively low enzyme loadings.     

A cellobiohydrolase from a thermophilic actinomycete,Microbispora bispora

A screening for thermophilic cellulolytic microbes from the soils of volcanic areas yielded several potentially useful bacteria. Of these,Microbispora bispora was the most useful. The enzyme complex was stable at 60–65‡C. Analysis of the complex indicated the presence of endoglucanase, cellobiohydrolase, and Β-glucosidase components. The two former enzymes were secreted, whereas the Β-glucosidase was cell-associated. The cellobiohydrolase was of particular interest, since this type of enzyme has rarely been reported from bacteria, and therefore was characterized in greater detail. Its mechanism of action was clarified through its action pattern towards soluble (and reduced) oligosaccharides. Synergism was observed between the cellobiohydrolase and endoglucanases during attack on crystalline cellulose (cotton and Avicel). This represents one of the first demonstrations of synergism in a procaryotic cellulase system.     

Mixed submerged fermentation with two filamentous fungi for cellulolytic and xylanolytic enzyme production

The efficient saccharification of lignocellulosic materials requires the cooperative actions of different cellulase enzyme activities: exoglucanase, endoglucanase, β-glucosidase, and xylanase. Previous studies with the fungi strains Aureobasidium sp. CHTE-18, Penicillium sp. CH-TE-001, and Aspergillus terreus CH-TE-013, selected mainly because of their different cellulolytic and xylanolytic activities, have demonstrated the capacity of culture filtrates of cross-synergistic action in the saccharification of native sugarcane bagasse pith. In an attempt to improve the enzymatic hydrolysis of different cellulosic materials, we investigated a coculture fermentation with two of these strains to enhance the production of cellulases and xylanases. The 48-h batch experimental results showed that the mixed culture of Penicillium sp. CH-TE-001 and A. terreus CH-TE-013 produced culture filtrates with high protein content, cellulase (mainly β-glucosidase), and xylanase activities compared with the individual culture of each strain. The same culture conditions were used in a simple medium with mineral salts, corn syrup liquor, and sugarcane bagasse pith as the sole carbon source with moderate shaking at 29°C. Finally, we compared the effect of the cell-free culture filtrates obtained from the mixed and single fermentations on the saccharification of different kinds of cellulosic materials.     

Cellulases and Hemicellulases from Endophytic <Emphasis Type="Italic">Acremonium</Emphasis> Species and Its Application on Sugarcane Bagasse Hydrolysis

The aim of this work was to have cellulase activity and hemicellulase activity screenings of endophyte Acremonium species (Acremonium zeae EA0802 and Acremonium sp. EA0810). Both fungi were cultivated in submerged culture (SC) containing l-arabinose, d-xylose, oat spelt xylan, sugarcane bagasse, or corn straw as carbon source. In solid-state fermentation, it was tested as carbon source sugarcane bagasse or corn straw. The highest FPase, endoglucanase, and xylanase activities were produced by Acremonium sp. EA0810 cultivated in SC containing sugarcane bagasse as a carbon source. The highest β-glucosidase activity was produced by Acremonium sp. EA0810 cultivated in SC using d-xylose as carbon source. A. zeae EA0802 has highest α-arabinofuranosidase and α-galactosidase activities in SC using xylan as a carbon source. FPase, endoglucanase, β-glucosidase, and xylanase from Acremonium sp. EA0810 has optimum pH and temperatures of 6.0, 55 °C; 5.0, 70 °C; 4.5, 60 °C; and 6.5, 50 °C, respectively. α-Arabinofuranosidase and α-galactosidase from A. zeae EA0802 has optimum pH and temperatures of 5.0, 60 °C and 4.5, 45 °C, respectively. It was analyzed the application of Acremonium sp. EA0810 to hydrolyze sugarcane bagasse, and it was achieved 63% of conversion into reducing sugar and 42% of conversion into glucose.     

TheTalaromyces emersonii enzyme system

In typical fermentations at 45‡C on cellulose/corn steep liquor/ammonium and mineral salts medium, growth of the thermophilic fungusTalaromyces emersonii increases rapidly up to about 50 h and then decreases, presumably because of cell lysis, sporulation, or both. The accumulation of cellulase activity follows closely on growth and essentially reaches a maximum at about the same time that cell protein does. By contrast, two peaks of Β-glucosidase activity are observed, one maximal at about 36 h and the second at about 75 h. Fractionation of culture filtrates showed that the cellulase system is comprised of at least four endoglucanases (EC 3.2.1.4), four or five exoglucanases (cello-biohydrolase; EC 3.2.1.91), and three types of Β-glucosidase (cellobiase; EC 3.2.1.21). All are glycoproteins. Indeed, variation in carbohydrate content may account for some of the observed multiplicity of enzyme forms. Although none of the individual components is active against cellulose, reconstitution experiments show that appropriate mixtures of each type act synergistically to effect hydrolysis of substrate. In addition to the three extracellular Β-glucosidases I (M_r, 135,000), II (M_r, 100,000), and III (M_r, 45,700), an intracellular form, IV (M_r, 57,600), has been isolated. All exist as single polypeptides. The extracellular forms I and III are most active at 70‡C, pH 5, and have half-lives under these conditions of 6 and 3 h, respectively. By contrast, the intracellular form (IV) is most active at 35‡C and is rapidly denatured at higher temperatures. Substrate specificity and other studies provide clues to their possible roles in vivo. Β-Glucosidase III acts as an exoglucohydrolase by removing glucose residues from cellooligosaccharides arising from the action of endocellulases. Β-Glucosidase I is the major enzyme involved in cleaving cellobiose and short chain cellooligosaccharides. In doing so it relieves the inhibition by cellobiose of cellulase action. The intracellular form, Β-glucosidase IV, may have a dual role. By virtue of its transferase activity it may convert incoming cellobiose to the active inducer of cellulase synthesis, whereas by cleaving cellobiose to glucose (hydrolase action) it provides energy for the cell and a repressor of cellulase formation. Four endocellulases have been purified to apparent homogeneity as judged by electrophoresis. Preliminary results show that they all have M_r values of about 70,000 and pI values less than 4. However, they differ from one another in carbohydrate content, thermal stability, and affinity for substrate. The complete cellulase system is most active at pH 4.2, 60–65‡C, and retains about 80% of its original activity after 5 d incubation at 60‡C, pH 5. Avicel and filter paper most effectively induce synthesis of the complete cellulase system, as measured by the ability of culture filtrate to digest filter paper. Cotton, Solka floc, and α-cellulose are also effective inducers, as are “wastes” such as newspaper, straw, and beet pulp. Little or no cellulase synthesis is evident when lactose, cellobiose, or glucose replaces cellulose in growth media. From a practical viewpoint we find that saccharification of beet pulp is most readily achieved by using enzyme (i.e., culture filtrate) obtained by growing the organism on medium containing beet pulp as the source of cellulose. Of the various strains ofTalaromyces emersonii investigated for cellulase production, we found CBS 814.70 to be the best, yielding approx. 0.5 IU/mL of culture filtrate. By medium optimization and genetic manipulation we have isolated a number of mutants of this strain giving 2 IU/mL or more and enzyme productivities of 20–25 IU/L/h. Xylanase, arabinogalactanase, and pectinase activities have also been detected in culture filtrates of the organism when grown on beet pulp. Various lignocellulosic materials, including cotton, Solka floc, Avicel, filter paper, newspaper, and straw, can be degraded by the enzyme system. However, much of our effort has been directed to investigation of the saccharification of beet pulp since it is available in large quantities at central locations and because its lignin content is low. About 85% of the dry weight of this material is accounted for by cellulose, hemicellulose, and pectin in roughly equal proportions. Culture filtrates effect significant saccharification of pulp as measured by the release of reducing sugars or of glucose. Ball-milling the pulp prior to incubation with enzyme effects considerable improvement in the extent of digestion. Alkali or peracetic acid pretreatment of the ball-milled substrate facilitates enzymic hydrolysis even further. Good results are also obtained when unmilled pulp is (a) pretreated with pectinase prior to incubation with normal culture filtrates or (b) incubated with more concentrated culture filtrates with good pectinase activity. Under suitable conditions, 80% hydrolysis of beet pulp polysaccharides was achieved in 5 d at 60‡C, pH 5.     

Characterisation of Specific Activities and Hydrolytic Properties of Cell-Wall-Degrading Enzymes Produced by Trichoderma reesei Rut C30 on Different Carbon Sources

Conversion of lignocellulosic substrates is limited by several factors, in terms of both the enzymes and the substrates. Better understanding of the hydrolysis mechanisms and the factors determining their performance is crucial for commercial lignocelluloses-based processes. Enzymes produced on various carbon sources (Solka Floc 200, lactose and steam-pre-treated corn stover) by Trichoderma reesei Rut C30 were characterised by their enzyme profile and hydrolytic performance. The results showed that there was a clear correlation between the secreted amount of xylanase and mannanase enzymes and that their production was induced by the presence of xylan in the carbon source. Co-secretion of α-arabinosidase and α-galactosidase was also observed. Secretion of β-glucosidase was found to be clearly dependent on the composition of the carbon source, and in the case of lactose, 2-fold higher specific activity was observed compared to Solka Floc and steam-pre-treated corn stover. Hydrolysis experiments showed a clear connection between glucan and xylan conversion and highlighted the importance of β-glucosidase and xylanase activities. When hydrolysis was performed using additional purified β-glucosidase and xylanase, the addition of β-glucosidase was found to significantly improve both the xylan and glucan conversion.     

The Effects of Wheat Bran Composition on the Production of Biomass-Hydrolyzing Enzymes by Penicillium decumbens

The effects of the starch, protein, and soluble oligosaccharides contents in wheat bran on the extracellular biomass-hydrolyzing enzymes activities released by Penicillium decumbens mycelia grown in batch fermentations have been examined. The results showed increased starch content correlated directly with an increase in released amylase activity but inversely with the levels of secreted cellulase and xylanase. High amounts of protein in wheat bran also reduced the activities of cellulase, xylanase and protease in the culture medium. The effects of the soluble and insoluble components of wheat bran and cello-oligosaccharides supplements on production of extracellular cellulase and xylanase were compared. The soluble cello-oligosaccharides compositions in wheat bran were proved to be one of the most significant factors for cellulase production. According to the results of this research, determining and regulating the composition of wheat bran used as a fermentation supplement may allow for improved induction of cellulase and xylanase production.     

Evaluation of cellulase preparations for hydrolysis of hardwood substrates

Seven cellulase preparations from Penicillium and Trichoderma spp. were evaluated for their ability to hydrolyze the cellulose fraction of hardwoods (yellow poplar and red maple) pretreated by organosolv extraction, as well as model cellulosic substrates such as filter paper. There was no significant correlation among hydrolytic performance on pretreated hardwood, based on glucose release, and filter paper activity. However, performance on pretreated hardwood showed significant correlations to the levels of endogenous β-glucosidase and xylanase activities in the cellulase preparation. Accordingly, differences in performance were reduced or eliminated following supplementation with a crude β-glucosidase preparation containing both activities. These results complement a previous investigation using softwoods pretreated by either organosolv extraction or steam explosion. Cellulase preparations that performed best on hardwood also showed superior performance on the softwood substrates.