Fractionation of β-Glucosidases and Related Extracellular Enzymes from Aspergillus niger

Industrial concentrates from Aspergillus niger culture filtrates were fractionated by ion-exchange and adsorption chromatography. Several other types of hydrolases were completely removed. Eight partially purified components were obtained. Using specific activity as an estimate of purification, one aryl-β-glucosidase was purified 35-fold. Another component showed 147-fold purification using a viscosimetric assay with carboxymethylcellulose as substrate. The aryl-β-glucosidase was distinctly more thermolabile than the carboxymethylcellulase.     

Optimization of β-glucosidase production from Aspergillus niger

本研究对Aspergillus niger Glu05生产β-葡萄糖苷酶的培养基组分及培养条件进行了优化.优化后的培养基组成和培养条件分别为:麸皮4％,tryptone 4％,1μmol MnSO4,1μmol NaCl,KH2PO40.2％,oH自然,摇床转速250 r/min,培养温度30℃,培养周期5d.优化后发酵液中酶活力达到44.11 IU/mL,与初始的产酶水平32.87 IU/mL相比,提高了36％.     

Production and characterization of β-glucosidases from different Aspergillus strains

-D-Glucosidase enzymes (-D-glucoside glucohydrolase, EC 3.2.1.21) from different Aspergillus strains (Aspergillus phoenicis, A. niger and A. carbonarius) were examined with respect to the enzyme production of the different strains using different carbon sources and to the effect of the pH and temperature on the enzyme activity and stability. An efficient and rapid purification procedure was used for purifying the enzymes. Kinetic experiments were carried out using p-nitrophenyl -D-glucopyranoside (pNPG) and cellobiose as substrates. Two different fermentation methods were employed in which the carbon source was glucose or wheat bran. Aspergillus carbonarius proved to be the less effective strain in -glucosidase production. Aspergillus phoenicis produced the highest amount of -glucosidase on glucose as carbon source however on wheat bran A. niger was the best enzyme producer. Each Aspergillus strain produced one single acidic -glucosidase with pI values in the range of pH 3.52–4.2. There was no significant difference considering the effect of the pH and temperature on the activity and stability among the enzymes from different origins. The enzymes examined have only -glucosidase activity. The kinetic parameters showed that all enzymes hydrolysed pNPG with higher efficiency than cellobiose. This shows that hydrophobic interaction plays an important role in substrate binding. The kinetic parameters demonstrated that there was no significant difference among the enzymes from different origins in hydrolysing pNPG and cellobiose as the substrates.     

Synthesis of cello-oligosaccharides from cellobiose with β-glucosidase II from Aspergillus niger

An extracellular -glucosidase II of Aspergillus niger catalysed the synthesis of cello-oligosaccharides from cellobiose (15%, w/v). The enzyme was stable at and below 4°C for at least 230 days and also stable at 30°C with the presence of 2.0% (w/v) cellobiose. The maximum yield of cello-oligosaccharides was about 30% (mol/mol), based on cellobiose (130 mg/mL) consumed. © Rapid Science Ltd. 1998     

Synthesis of alkyl β-glucosides from cellobiose with Aspergillus niger β-glucosidase II

An extracellular -glucosidase II of Aspergillus niger catalyzed the synthesis of methyl -glucoside and ethyl -glucoside with 5.0% (v/v) cellobiose as glucosyl donor in a biphasic media containing 20% (v/v) methanol and 30% (v/v) ethanol, respectively. The maximum yield of methyl -glucoside and ethyl -glucoside was 83% (mol/mol; 12 mg/ ml) and 53% (mol/mol; 5.5 mg/ml), based on cellobiose consumed. © Rapid Science Ltd. 1998     

Over-production of β-glucosidase by Aspergillus niger mutant from lignocellulosic biomass

The maximum yield of -glucosidase by A. niger KK2 mutant, grown on the basal medium for 7 days, was 514 I U g^–1 ground rice straw, and was about twice those obtained from wheat straw or bran by previous researchers. Optimal activity of -glucosidase was at 60–70 °C and pH 4.8.     

Isolation and characterization of β-glucosidases from Aspergillus nidulans mutant USDB 1183

Two extracellular -glucosidases (cellobiase, EC 3.2.1.21), I and II, from Aspergillus nidulans USDB 1183 were purified to homogeneity with molecular weights of 240,000 and 78,000, respectively. Both hydrolysed laminaribiose, -gentiobiose, cellobiose, p-nitrophenyl--L-glucoside, phenyl--L-glucoside, o-nitrophenyl--L-glucoside, salicin and methyl--L-glucoside but not -linked disaccharides. Both were competitively inhibited by glucose and non-competitively (mixed) inhibited by glucono-1,5-lactone. -Glucosidase I was more susceptible to inhibition by Ag⁺ and less inhibited by Fe²⁺ and Fe³⁺ than -glucosidase II.     

β-glucosidases from a new Aspergillus species can substitute commercial β-glucosidases for saccharification of lignocellulosic biomass

β-Glucosidase activity plays an essential role for efficient and complete hydrolysis of lignocellulosic biomass. Direct use of fungal fermentation broths can be cost saving relative to using commercial enzymes for production of biofuels and bioproducts. Through a fungal screening program for β-glucosidase activity, strain AP (CBS 127449, Aspergillus saccharolyticus ) showed 10 times greater β-glucosidase activity than the average of all other fungi screened, with Aspergillus niger showing second greatest activity. The potential of a fermentation broth of strain AP was compared with the commercial β-glucosidase-containing enzyme preparations Novozym 188 and Cellic CTec. The fermentation broth was found to be a valid substitute for Novozym 188 in cellobiose hydrolysis. The Michaelis-Menten kinetics affinity constant as well as performance in cellobiose hydrolysis with regard to product inhibition were found to be the same for Novozym 188 and the broth of strain AP. Compared with Novozym 188, the fermentation broth had higher specific activity (11.3?U/mg total protein compared with 7.5 U/mg total protein) and also increased thermostability, identified by the thermal activity number of 66.8 vs. 63.4?°C for Novozym 188. The significant thermostability of strain AP β-glucosidases was further confirmed when compared with Cellic CTec. The β-glucosidases of strain AP were able to degrade cellodextrins with an exo-acting approach and could hydrolyse pretreated bagasse to monomeric sugars when combined with Celluclast 1.5L. The fungus therefore showed great potential as an onsite producer for β-glucosidase activity.     

Fed-batch biotransformation of β-ionone by Aspergillus niger

Aspergillus niger IFO 8541 was found to be an efficient biocatalyst for the biotransformation of -ionone into hydroxy and oxo derivatives. The reaction had to be carried out with an inoculum made of about 4 × 10⁷ fresh spores/l and with a preliminary growth period giving at least 3 g/l biomass. The fungus developed in the form of pellets when cultivated as free mycelium; entrapment of the microorganism in calcium alginate beads was an efficient way to mimic this feature in an aerated, stirred bioreactor. The biotransformation was carried out using a fed-batch mode of operation involving sequential precursor addition. -Ionone stopped the fungal growth and was converted into metabolites only when the carbon source remained present in the medium; it was fully oxidized after sucrose exhaustion. These conditions allowed recovery of about 2.5 g/l aroma compounds after 230 h cultivation with a molar yield close to 100%.     

Production of Aspergillus niger β-mannosidase in Pichia pastoris

β-Mannosidase (EC 3.2.1.25) is an exoglycosidase specific for the hydrolysis of terminal β-linked mannoside in various sugar chains. cDNA corresponding to the β-mannosidase gene was cloned from Aspergillus niger, sequenced, and expressed in the yeast Pichia pastoris. The β-mannosidase gene contains an open reading frame which encodes the protein with 933 amino acid residues. The wild type and recombinant proteins were purified to apparent homogeneity and biochemically characterized (K(M) 0.28 and 0.44mmol/l for p-nitrophenyl β-d-mannopyranoside, pI 4.2 and 4.0, and their pH optima were at pH 4.5 and 5.5 and 65°C, respectively).     

Detection of endogenous β-glucuronidase activity in Aspergillus niger

 An endogenous β-glucuronidase that hydrolyses the chromogenic substrate 5-bromo-4-chloro-3-indolyl-β-D-glucuronide (X-gluc) in Aspergillus niger is reported. The activity was induced when the fungus was grown in media containing xylan, but was either very low, or absent, when grown on glucose. Endogenous β-glucuronidase was primarily located in newly formed hyphae, and was apparent at pH values between 3 and 6. Hydrolysis of X-gluc was sensitive to the inhibitor D-saccharic acid 1,4-lactone and was irreversibly inactivated by heating. The bacterial uidAβ-glucuronidase reporter gene was strongly expressed in the hyphae of transformed A. niger but, in contrast to the endogenous activity, the enzyme was also active at pH 7–8.5. Histochemical localization of uidA expression in A. niger, without interference from the endogenous β-glucuronidase activity, was achieved by staining at this pH. Received : 22 March 1995/Received last revision : 17 August 1995/Accepted : 22 August 1995     

Enhancing the activity and thermostability of thermostable β-glucosidase from a marine Aspergillus niger at high salinity

To evaluate the effect of salinity on the catalyzing ability of β-glucosidase in the marine fungus Aspergillus niger, the thermodynamic parameters of the β-glucosidase were investigated at different salinities. At the optimum salinity of 6% NaCl (w/v) solution, the optimum temperature and pH of the β-glucosidase activity was 66 °C and 5.0, respectively. Under these conditions, the β-glucosidase activity increased 1.46 fold. The half-life of denaturation in 6% NaCl (w/v) solution was approximately twice as long as that in NaCl free solution. The Gibb's free energy for denaturation, ΔG, was 2 kJ/mol higher in 6% NaCl (w/v) solution than in NaCl free solution. The melting point (68.51 °C) in 6% NaCl (w/v) solution was 1.71 °C higher than that (66.80 °C) in NaCl free solution. Similarly, the activity and thermostability of the pure β-glucosidase increased remarkably at high salinity. The thermostable β-glucosidase, of which the activity and the thermostability are remarkably enhanced at high salinity, is valuable for industrial hydrolyzation of cellulose in high salinity environments.     

Properties of β-glucosidase purified from Aspergillus niger mutants USDB 0827 and USDB 0828

Summary Two extracellular -glucosidases (EC 3.2.1.21) were isolated from Aspergillus niger USDB 0827 and A. niger USDB 0828, and their physical and kinetic properties studied. Both enzymes were very similar in terms of molecular size (230000 Da), pH optimum (pH 4.6), temperature optimum (65° C), stability at high temperatures and substrate preferences. They were capable of hydrolysing -linked disaccharides, phenyl -d-glucoside, p-nitrophenyl -d-glucoside (PNPG), o-nitrophenyl -d-glucoside, salicin and methyl -d-glucoside but lacked activity towards -linked disaccharides, a range of p-nitrophenyl monoglycosides and p-nitrophenyl diglycosides. Both -glucosidases were better at hydrolysing cellobiose than cellotriose, cellotetraose or cellopentaose. For both enzymes, glucose showed competitive inhibition with PNPG as substrate but had no effect with cellobiose. However, the two -glucosidases differed in inhibition by glucono-1,5-lactone and affinity for cellobiose. -Glucosidase from A. niger USDB 0827 also gave lower specific activity, and was more susceptible to metal ions (Ag⁺, Fe²⁺ and Fe³⁺) inhibition than that of A. niger USDB 0828. Correspondence to: Y. K. Hoh     

Properties of a β-(1→4)-glucan hydrolase from Aspergillus niger

1. A beta-(1-->4)-glucan hydrolase prepared from Aspergillus niger, as described by Clarke & Stone (1965a), showed a pH optimum in the range 4.5-6 and K(m) 0.25% when acting on a cellulose dextrin sulphate substrate. 2. The hydrolase rapidly decreased the specific viscosity of carboxymethylcellulose with a small increase in the production of reducing sugars. The identity of the products of hydrolysis of cellotetraose, cellopentaose and their reduced analogues indicate a preferential cleavage of non-terminal glucosidic linkages. The enzyme may be described as beta-(1-->4)-glucan 4-glucanohydrolase (EC 3.2.1.4). 3. In addition to carboxymethylcellulose, cellulose dextrins, cellopentaose and cellotetraose the enzyme fraction hydrolysed lichenin, oat and barley glucans, ivory-nut mannan and a glucomannan from Konjak flour. No hydrolysis of wheat-straw beta-(1-->4)-xylan, Lupinus albus beta-(1-->4)-galactan, pneumococcal type III polysaccharide, chitin, hyaluronic acid, laminarin, pachydextrins, carboxymethylpachyman or beta-(1-->3)-oligoglucosides was detected. 4. The hydrolase showed no transglycosylase activity from cellodextrin or cellopentaose substrates to glucose or methanol acceptors. 5. The hydrolysis of cellodextrins was inhibited completely by 1.0mm-Hg(2+), 0.7mm-phenylmercuric nitrate and 1.0mm-iodine.     

Distinctive Properties of β-Glucosidases and Related Enzymes Derived from a Commercial Aspergillus niger Cellulase

Eight highly purified β-glucosidases from Aspergillus niger were compared enzymatically, chemically, and immunologically. Ultraviolet spectra, pH-activity responses, substrate specificities, thermal stabilities, kinetic changes in the viscosity of substrate, Michaelis-Menten parameters, adsorption characteristics on cellulose, and exclusion characteristics on dextran gels were determined. The data indicate that the several components represent distinctly different enzymes in terms of mode of attack on substrate. The concept of partial denaturation of a single enzyme precursor is unable to explain the heterogeneity observed. Comparison of the effect of pH on hydrolysis of carboxymethylcellulose and cellohexaose suggests that a negative charge center on the substrate has a pronounced inhibitory effect on the enzymes.