Enzymatic hydrolysis of cellulose to glucose lung immobilized β-glucosidase

The production of sugars by enzymatic hydrolysis of cellulose is a multistep process which includes conversion of the intermediate cellobiose to glucose by β-glucosidase. Aside from its role as an intermediate, cellobiose inhibits the endoglucanase components of typical cellulase enzyme systems. Because these enzyme systems often contain insufficient concentrations of β-glucosidase to prevent accumulation of inhibitory cellobiose, this research investigated the use of supplemental immobilized β-glucosidase to increase yield of glucose. Immobilized β-glucosidase from Aspergillus phoenicis was produced by sorption at controlled-pore alumina with about 90% activity retention. The product lost only about 10% of the original activity during an on-stream reaction period of 500 hr with cellobiose as substrate; maximum activity occurred near pH 3.5 and the apparent activation energy was about 11 kcal/mol. The immobilized β-glucosidase was used together with Trichoderma reesei cellulase to hydrolyze cellulosic materials, such as Solka Floc, corn stove and exploded wood. Increased yields of glucose and greater conversions of cellobiose of glucose were observed when the reaction systems contained supplemental immobilized β-glucosidase.     

Isolation and some properties of two extracellular β-glucosidases from Trichosporon adeninovorans

The yeast Trichosporon adeninovorans secretes two multiple forms of β-glucosidase at a high rate if grown in a medium containing cellobiose. Following mutagenesis a mutant strain resistant to 2-deoxy-D-glucose was selected. This strain produced more β-glucosidase activity and had acquired a strong resistance against repression by glucose. The β-glucosidases were separated one from each other by chromatography on hydroxylapatite and by gel filtration. Both enzymes have similar properties. The optimal temperature for their activity was 60 to 63°C and the enzymes displayed highest activity at pH of 4.5. The molecular weight of β-glucosidase I was found to be 570,000 and that for β-glucosidase II was 525,000. The K_m value for cellobiose was determined to be 4.1 mM for β-glucosidase I and 3.0 mM for β-glucosidase II.     

The inhibition of β-glucosidase activity in Trichoderma reesei C30 cellulase by derivatives and isomers of glucose

The inhibition of β-glucosidase in Trichoderma reesei C30 cellulase by D -glucose, its isomers, and derivatives was studied using cellobiose and ρ-nitrophenyl-β-glucoside (PNPG) as substrates for determining enzyme activity. The enzymatic hydrolysis of both substrates was inhibited competitively by glucose with approximate K_i values of 0.5mM and 8.7mM for cellobiose and PNPG as substrate, respectively. This inhibition by glucose was maximal at pH 4.8, and no inhibition was observed at pH 6.5 and above. The α anomer of glucose inhibited β-glucosidase to a greater extent than did the β form. Compared with D -glucose, L -glucose, D -glucose-6-phosphate, and D -glucose-1-phosphate inhibited the enzyme to a much lesser extent, unlike D -glucose-L -cysteine which was almost as inhibitory as glucose itself when cellobiose was used as substrate. Fructose (2?100mM) was found to be a poor inhibitor of the enzyme. It is suggested that high rates of cellobiose hydrolysis catalyzed by β-glucosidase may be prolonged by converting the reaction product glucose to fructose using a suitable preparation of glucose isomerase.     

Trans-glycosylation capacity of a highly glycosylated multi-specific β-glucosidase from Fusarium solani

An extracellular β-glucosidase from Fusaruim solani cultivated on wheat bran was purified by only two chromatographic steps. The purified enzyme exhibited optimal temperature and pH at 60 °C and pH 5, respectively. The purified β-glucosidase behaves as a very large protein due to its high degree of glycosylation. More interestingly, the endoglycosidase H (Endo H) treatment led to 97.55% loss of its initial activity after 24 h of treatment. Besides, the addition of Tunicamycin (nucleoside antibiotic blocking the N-glycosylation first step) during the culture of the fungus affected seriously the glycosylation of the enzyme. Both treatments (endo H and Tunicamycin) strengthened the idea that the hyperglycosylation is involved in the β-glucosidase activity and thermostability. This enzyme was also shown to belong to class III of β-glucosidases (multi-specific) since it was able to act on either cellobiose, gentiobiose or sophorose which are disaccharide composed of two units of d-glucose connected by β1–4, β1–6 and β1–2 linkage, respectively. The β-glucosidase activity was strongly enhanced by ferrous ion (Fe²⁺) and high ionic strength (1 M KCl). The purified enzyme exhibited an efficient transglycosylation capacity allowing the synthesis of cellotriose and cellotetraose using cellobiose as donor.

     

Purification and Characterization of two Extracellular β-Glucosidases from Trichoderma viride ITCC 1433

T. viride ITCC 1433 synthesizes a two component system for the hydrolysis of cellobiose and cellooligodextrins. 80% of the total activity are solubilized during growth. The large protein (A), mol. weight 98 000 d, is glycosylated and slightly acidic (pH = 6.1). The smaller protein (B), mol. weight 70 000 d, is unglycosylated and neutral (pH = 7.2). Both proteins form a two-step system where β-glucosidase A is active at low substrate concentrations (K_M = 2.3 × 10^?4 M cellobiose) while β-glucosidase B covers the range of 10-fold higher cellobiose concentrations (K_M = 1.8 × 10^?3 M). The enzymes are fairly stable with a residual activity of 70% at 50°C after 24 h.     

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.     

Cellotriose Synthesis Using d-Glucose as a Starting Material by Two Step Reactions of Immobilized β-Glucosidases

We tried to polymerize d-glucose to cellotriose, the smallest substrate for β-1,4-glucan synthesis by the β-transglycosylase of Trichoderma longibrachiatum, without participation of high energy compounds such as nucleotide sugars. A commercial β-glucosidase (sweet almond) showed a typical condensation reaction of d-glucose, producing cellobiose when it was entrapped in a visking tube and incubated in 30% d-glucose solution. The reaction was done with immobilized enzyme covalently bound to Polyacrylamide beads, and entrapped enzyme. Cellobiose (21.0 mg) was obtained from 30 g of d-glucose in a 3-day reaction, where 0.29 unit of the entrapped enzyme preparation was incubated with 100 ml of 30% d-glucose at pH 6.0 and 41°C. Gentiobiose was also produced in the mixture as a minor product. The immobilized β-glucosidase (Sumizyme C) preparation covalently bound to Polyacrylamide beads could catalyze a transglucosylation reaction to produce cellotriose from cellobiose in a good yield without production of gentiobiose. The transfer reaction was optimal at pH 4.8 and 30°C. Cellotriose (11.2 mg) was produced from the reaction mixture containing 68 mg of cellobiose and the enzyme preparation (0.1 unit) after 24-hr of incubation at the optimal conditions. Both immobilized β-glucosidases, sweet almond and Sumizyme C, may be used repeatedly without any loss of the initial activity.     

Immobilization of β-glucosidase on an inorganic carrier

The enzymatic hydrolysis of cellobiose, an important intermediate of the decomposition of cellulose containing materials, with immobilized β-glucosidase preparations from Geotrichium candidum, Trichoderma lignorum and Aspergillus foetidus was examined At first it was the aim to prepare from differently purified samples with different specific cellobiase activities high active preparations on the basis of the inorganic carrier Silochrom S-80. Characteristics e.g. thermal stability and temperature and pH optimum of immobilized preparations were compared with those of soluble preparations Kinetics of cellobiose hydrolysis by immobilized enzyme preparations were studied.     

Some Properties of Transglycosylation Activity of Sesame β-Glucosidase

The transglycosylation reaction of partially purified β-glucosidase from sesame seeds with cellobiose is described. Sesame β –glucosidase was partially purified by ammonium sulfate fractionation and gel filtration. The molecular weight of the enzyme was 200,000 by gel filtration. Sesame β-glucosidase showed strong transfer activity to synthesize the trisaccharide from cellobiose. The optimum pH and temperature of the transglycosylation reaction were pH 4.0 and 60°C.     

Purification, characterization, and properties of beta-glucosidase enzymes from Sclerotium rolfsii

Four β-glucosidase enzymes were extensively purified from the culture filtrates of Sclerotium rolfsii and some of their physicochemical properties studied. All the enzymes showed a single protein band in sodium dodecyl sulfate-gel electrophoresis and in disc gel electrophoresis at pH 8.9 and 4.3. The purified β-glucosidases were free of endoglucanase (carboxymethyl cellulose viscosity-lowering activity). All the enzymes are glycoproteins and are composed of one polypeptide chain. The molecular weight of the four β-glucosidases varies between 90,000 and 107,000. The pH and temperature optima of the four β-glucosidases are 4.2 and 68 °C with p-nitrophenyl-β-d-glucoside and 4.5 and 65 °C with cellobiose as substrate. The isoelectric points for the enzymes are 4.10, 4.55, 5.10, and 5.55, respectively. The specific activities of the enzymes with cellobiose as substrate are 55, 78, 175, and 51 μmol glucose released per minute per milligram protein, respectively. The enzymes are inhibited by the reaction product glucose, and by glucono-δ-lactone and nojirimycin. A carboxylate group is implicated in the catalysis of β-glucosidase.     

Purification and Some Properties of Chaetomium trilaterale β-Xylosidase

A β-xyloside hydrolytic enzyme of the fungus Chaetomium trilaterale was further purified by a modification of Kawaminami’s procedure (DEAE-Sephadex A-25 and Sephadex G-75 column chromatography), followed by isoelectric focusing. The purified preparation was homogeneous by polyacrylamide disc gel electrophoreses at pH 4.3 and pH 8.3. The purified enzyme hydrolyzed β-d-glucopyranosides as well as β-d-xylopyranosides, and the ratio of β-glucosidase activity against β-xylosidase activity increased about 3 fold during the purification steps. The molecular weight of this preparation was estimated to be about 240,000 by Sephadex G-200 gel filtration and 118,000 by SDS-polyacrylamide slab gel electrophoresis. The isoelectric point was 4.86 and the amino acid composition was also determined.

The optimum pH was at 4.2 for phenyl β-d-glucoside and around 4.5 for phenyl β-d-xyloside. The β-xylosidase activity was relatively stable but β-glucosidase activity was rapidly inactivated, at the alkaline pH range above 11. The heating of the preparation at 60°C didn’t show a parallel inactivation of the two activities. N-Bromosuccinimide strongly inactivated both enzyme activities. Nojirimycin and glucono-l,5-lactone showed a stronger inhibition on β-xylosidase activity than on β-glucosidase activity. The maximal velocities decreased in the order; phenyl β-d-glucoside > cellobiose > phenyl β-d-xyloside > xylobiose; the value with phenyl β-d-glucoside was about 28-fold higher than that with phenyl β-d-xyloside.     

Cellobiose metabolism and cellobiohydrolase I biosynthesis by Trichoderma reesei

The relationship between β-linked disaccharide (cellobiose, sophorose) utilization and cellulase, particularly cellobiohydrolase I (CBH I) synthesis by Trichoderma reesei, was investigated. During growth on cellobiose and sophorose as carbon sources in batch as well as resting-cell culture, only sophorose induced cellulase formation. In the latter experiments, sophorose was utilized at a much lower rate than cellobiose, and the more cellulase produced, the lower its rate of utilization. Cellobiose and sophorose were utilized by the fungus mainly via hydrolysis by the cell wall- and cell membrane-bound β-glucosidase. Addition of sophorose to T. reesei growing on cellulose did not further stimulate cellulase synthesis, and addition of cellobiose was inhibitory. Cellobiose, however, promoted cellulase formation in both batch and resting cell cultures, when its hydrolysis by β-glucosidase was inhibited by nojirimycin. No cellulase formation was observed when the uptake of glucose (produced from cellobiose by β-glucosidase) was inhibited by 3-O-methylglucoside. Cellodextrins (C₂ to C₆) promoted formation of low levels of cellobiohydrolase I in indirect proportion to their rate of hydrolysis by β-glucosidase. Studies on the uptake of [³H]cellobiose, [³H]sophorose, and [¹⁴C]glucose in the presence of inhibitors of β-glucosidase (nojirimycin) and glucose transport (3-O-methylglucoside) show that glucose transport occurs at a much higher rate than disaccharide hydrolysis. Extracellular disaccharide hydrolysis accounts for at least 95% of their metabolism. The presence of an uptake system for cellobiose was established by demonstrating the presence of intracellular labeled [³H]cellobiose in T. reesei after its extracellular supply. The data are consistent with induction of cellulase and particularly CBH I formation in T. reesei by β-linked disaccharides under conditions where their uptake is favored at the expense of extracellular hydrolysis.     

Isolation and Characterization of a β-Glucosidase from a Clavispora Strain with Potential Applications in Bioethanol Production from Cellulosic Materials

We previously reported on a new yeast strain of Clavispora sp. NRRL Y-50464 that is capable of utilizing cellobiose as sole source of carbon and energy by producing sufficient native β-glucosidase enzyme activity without further enzyme supplementation for cellulosic ethanol production using simultaneous saccharification and fermentation. Eliminating the addition of external β-glucosidase reduces the cost of cellulosic ethanol production. In this study, we present results on the isolation and identification of a β-glucosidase protein from strain Y-50464. Using Matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and blast search of the NCBInr database (National Center for Biotechnology Information nonredundant), the protein from Y-50464 was identified as a β-glucosidase (BGL1) with a molecular weight of 93.3 kDa. The BGL1 protein was purified through multiple chromatographic steps to a 26-fold purity (K _m?=?0.355 mM [pNPG]; K _i?=?15.2 mM [glucose]), which has a specific activity of 18.4 U/mg of protein with an optimal performance temperature at 45 °C and pH of 6.0. This protein appears to be intracellular although other forms of the enzyme may exist. The fast growth rate of Y-50464 and its capability to produce sufficient β-glucosidase activity for ethanol conversion from cellobiose provide a promising means for low-cost cellulosic ethanol production through a consolidated bioprocessing development.     

Utilization of cellobiose and production of β-clucosidase by nine yeast species

A comparative study of 9 yeasts namely, Candida blankii,C.humicola,C.ishiwadae,C.rhagii,C.tropicalis,Hensenula subpelliculosa,Saccharomyces cerevisiae,Trichosporon cutaneum and Tr.pullulans was carried out for the production of extracellular and cell bound β-glucosidase using cellobiose as the substrate. Trichosporon cutaneum was found to be the best extracellular as well as cell bound β-clucosidase producer and the former activity was more than the latter. In the rest of the yeasts most of them showed more cell bound β-glucosidase as compared to the extracellular.     

The bgl1 gene of Trichoderma reesei QM 9414 encodes an extracellular, cellulose-inducible β-glucosidase involved in cellulase induction by sophorose

We have investigated the effect of disruption of the bgl1-(β-glucosidase l-encoding) gene of Trichoderma reesei on the formation of other β-glucosidase activities and on the induction of cellulases. To this end the bgl1 locus was disrupted by insertion of the Aspergillus nidulans amdS (acetamidase-encoding) gene. The bgl1-disrupted strain did not produce the 75kDa extracellular β-glucosidase on cellulose or lactose, but still formed β-glucosidase activity on glucose, cellobiose, xylan or β-1,3-glucan, suggesting that the enzyme(s) exhibiting this β-glucosidase activity is (are) not encoded by bgl1. The cellulose-inducer sophorose induced the bgl1-encoded β-glucosidase, whereas the remaining β-glucosidase activity was induced by methyl-β-D-glucoside. The bgl1-gene product was mainly secreted into the medium, whereas the other β-glucosidase activity was mainly associated with the cells. A bgl1-multicopy strain formed higher amounts of cellulases than the parent strain. Nonsaturating concentrations of sophorose efficiently induced cellobiohydrolase I formation in the bgl1-multicopy strain, but less efficiently in the bgl1-disrupted strain. The multicopy strain and the parent strain were comparably efficient at saturating sophorose concentrations. The β-glucosidase inhibitor nojirimycin strongly inhibited induction in all strains. These data suggest that the bgl1-encoded β-glucosidase is not identical to the plasma-membrane-bound, constitutive, methyl-β-glucoside inducible β-glucosidase, but represents an extracellular cellulose-induced enzyme. Both enzymes contribute to rapid induction of cellulases by modifying the inducer sophorose.     

Purification and characterization of three β-glycosidases exhibiting high glucose tolerance from Aspergillus niger ASKU28

Production and utilization of cellulosic ethanol has been limited, partly due to the difficulty in degradation of cellulosic feedstock. β-Glucosidases convert cellobiose to glucose in the final step of cellulose degradation, but they are inhibited by high concentrations of glucose. Thus, in this study, we have screened, isolated, and characterized three β-glycosidases exhibiting highly glucose-tolerant property from Aspergillus niger ASKU28, namely β-xylosidase (P1.1), β-glucosidase (P1.2), and glucan 1,3-β-glucosidase (P2). Results from kinetic analysis, inhibition study, and hydrolysis of oligosaccharide substrates supported the identification of these enzymes by both LC/MS/MS analysis and nucleotide sequences. Moreover, the highly efficient P1.2 performed better than the commercial β-glucosidase preparation in cellulose saccharification, suggesting its potential applications in the cellulosic ethanol industry. These results shed light on the nature of highly glucose-tolerant β-glucosidase activities in A. niger, whose kinetic properties and identities have not been completely determined in any prior investigations.     

Overexpression of a multifunctional β-glucosidase gene from thermophilic archaeon Sulfolobus solfataricus in transgenic tobacco could facilitate glucose release and its use as a reporter

The β-glucosidase, which hydrolyzes the β(1–4) glucosidic linkage of disaccharides, oligosaccharides and glucose-substituted molecules, has been used in many biotechnological applications. The current commercial source of β-glucosidase is mainly microbial fermentation. Plants have been developed as bioreactors to produce various kinds of proteins including β-glucosidase because of the potential low cost. Sulfolobus solfataricus is a thermoacidophilic archaeon that can grow optimally at high temperature, around 80 °C, and pH 2–4. We overexpressed the β-glucosidase gene from S. solfataricus in transgenic tobacco via Agrobacteria-mediated transformation. Three transgenic tobacco lines with β-glucosidase gene expression driven by the rbcS promoter were obtained, and the recombinant proteins were accumulated in chloroplasts, endoplasmic reticulum and vacuoles up to 1%, 0.6% and 0.3% of total soluble protein, respectively. By stacking the transgenes via crossing distinct transgenic events, the level of β-glucosidase in plants could further increase. The plant-expressed β-glucosidase had optimal activity at 80 °C and pH 5–6. In addition, the plant-expressed β-glucosidase showed high thermostability; on heat pre-treatment at 80 °C for 2 h, approximately 70% residual activity remained. Furthermore, wind-dried leaf tissues of transgenic plants showed good stability in short-term storage at room temperature, with β-glucosidase activity of about 80% still remaining after 1 week of storage as compared with fresh leaf. Furthermore, we demonstrated the possibility of using the archaebacterial β-glucosidase gene as a reporter in plants based on alternative β-galactosidase activity.

     

Properties of theβ-glucosidase fromCellulomonas flavigena and fromEscherichia coli harboring the recombinant plasmid pJS3

Summary Plasmid-coded -glucosidase produced byEscherichia coli was characterized and compared to the enzyme produced byCellulomonas flavigena. Cell-free extracts, non-denaturing PAGE and 5-bromo-4-chloro-3-indolyl--d-glucopyranoside (X-glu) as substrate were used to compare both enzymes. The -glucosidase was assayed for cellobiose andp-nitrophenyl-glucopyranoside (PNPG). Cellobiose hydrolysis was performed at 50°C for the enzyme fromC. flavigena and at 37°C for that fromE. coli pJS3, both with an optimal pH of 6.5. For PNPG hydrolysis, the optimal conditions were pH 5.5 and 37°C for both cell extracts. Most of the -glucosidase activity was intracellular. When cultures ofC. flavigena were grown with cellobiose or carboxymethylcellulose (CMC) as inducers, the expression of -glucosidase was increased considerably.E. coli pJS3 produces a cellobiase which hydrolyzes cellobiose and PNPG. TheK _m values for cellobiose and PNPG indicated that the -glucosidase activity ofC. flavigena had a higher affinity for cellobiose as substrate, whereas the -glucosidase fromE. coli pJS3 showed higher affinity for PNPG.     

毁灭柱孢菌中一种人参皂苷Rb1水解酶的纯化及酶学性质研究

通过DEAE-纤维素阴离子交换层析、30％～80％（NH3）2SO3盐析、Sepharose CL-6B凝胶过滤层析和Mono Q HR5／5阴离子交换层析,从毁灭枉孢菌培养液中部分纯化出一种能够水解人参皂苷Rb,的β-葡萄糖苷酶F-I。F—I具有较好的pH稳定性和热稳定性,在pH4．0～11．0范围内和55℃以下表现出良好的β-葡萄糖苷酶活性,其最适pH为5．0,最适温度为55℃。EDTA、Cu^2＋和Zn^2＋对该酶活性有较强的抑制作用。底物专一性分析表明,F—I能高特异性水解人工合成的底物pNPG,还能水解β-葡萄糖苷键连接的二糖如纤维二糖和龙胆二糖,说明此酶为一种β-葡萄糖苷酶。F—I对人参皂苷Rb1表现了较强的水解活性,而对人参皂苷Rb2和Rc的水解活性较低。该酶水解人参皂苷Rb1的路径为Rb1→Rd→F2→C—K。F—I对人参皂苷Rb1的这种高效水解为稀有人参皂苷的工业制备奠定了基础。     

Products of enzymatic hydrolysis of cellulose and its derivatives

Cellobiose and glucose were determined in a mixture of the two carbohydrates by methods involving the use of glucose oxidase and of β-glucosidase.Paper-partition chromatography is used as a confirmatory method in the identification of the hydrolysis products and in the detection of the various constituents.The cellulolytic organisms studied produce large amounts of the enzyme Cx, which diffuses into the medium. Only small amounts of β-glucosidase are found outside the cell. Cellobiose resulting from Cx activity can enter the cells as rapidly as can glucose.The role of cellobiose as a principal product in the hydrolysis of cellulose is confirmed. It is hypothesized that the principal final product of Cx activity is cellobiose, and that the presence of cellobiase in the medium is not a prerequisite to utilization of cellobiose by the organism. This is a correction of the hypothesis previously published stating that glucose appeared to be the final product of Cx activity.