Comparison of Immobilized and Free Amyloglucosidase Process in Glucose SyrupsProduction from White Sorghum Starch

Optimum conditions for glucose syrups production from white sorghum were studied through sequential liquefaction and saccharification processes. In the liquefaction process, a maximum dextrose equivalent (DE) of 10.98 % was achieved using 30 % (w/v) of starch and Termamyl ɑ-amylase from Bacillus licheniformis. Saccharification was performed by free and immobilized amyloglucosidase from Rhizopus mold at 1 % (w/v). DE values of 88.32 % and 79.95 % were obtained from 30 % (w/v) of starch with, respectively, free and immobilized enzyme. The immobilized Amyloglucosidase in calcium alginate beads showed reusable capacity for up to 6 cycles with 46 % of the original activity retained. The kinetic behaviour of immobilized and free enzyme gives K_m value of 22.13 and 16.55 mg mL⁻¹ and V_max of 0.69 and 1.61 mg mL⁻¹ min⁻¹, respectively. The hydrolysis yield using immobilized amyloglucosidase were lower than that of the free one. However, it is relevant to reuse enzyme without losing activity in order to trim down the overall costs of enzymatic bioprocesses as starch transformation into required products in industrial manufacturing. Hydrolysis of sorghum starch using immobilized amyloglucosidase represents a promising alternative towards the development of the glucose syrups production process and its utilization in various industries.     

Pullulanases of alkaline and broad pH range from a newly isolated alkalophilicBacillus sp. S-1 and aMicrococcus sp. Y-1

Summary Two highly alkalophilic bacteria, and potent producers of alkaline pullulanase, were isolated from Korean soils. The two isolates, identified asBacillus sp. S-1 andMicrococcus sp. Y-1, grow on starch under alkaline conditions and effectively secrete extracellular pullulanases. The two isolates were extremely alkalophilic since bacterial growth and enzyme production occurred at pH values ranging from pH 6.0 to 12.0 forMicrococcus sp. Y-1 and pH 6.0 to 10.0 forBacillus sp. S-1. Both strains secrete enzymes that possess amylolytic and pullulanolytic acitivities. Extracellular crude enzymes of both isolates gave maltotriose as the major product formed from soluble starch and pullulan hydrolysis. Compared to other alkalophilic microbes such asMicrococcus sp. (0.57 units ml^–1),Bacillus sp. KSM-1876 (0.56 units ml^–1) andBacillus No. 202-1 (1.89 units ml^–1) these isolates secreted extremely high concentrations (7.0 units ml^–1 forBacillus sp. S-1 and 7.6 units ml^–1 forMicrococcus sp. Y-1) of pullulanases in batch culture. The pullulanase activities from both strains were mostly found in the culture medium (85–90%). The extracellular enzymes of both bacteria were alkalophilic and moderately thermoactive; optimal activity was detected at pH 8.0–10.0 and between 50 and 60°C. Even at pH 12.0, 65% of original Y-1 pullulanase activity and 10% of S-1 pullulanase activity remained. The two newly isolated strains had broad pH ranges and moderate thermostability for their enzyme activities. These result strongly indicate that these new bacterial isolates have potential as producers of pullulanases for use in the starch industry.     

Production of maltose and maltotriose from starch and pullulan by a immobilized multienzyme of pullulanase and β-amylase

Pullulanase was immobilized on tannic acid and TEAE-cellulose, and β-amylase was covalently immobilized on p-aminobenzylcellulose. Both the immobilized enzymes showed similar properties in pH and temperature optima and heat stability. On passing the pullulan solution at high temperature (50°C) through a column packed with immobilized pullulanase, only maltotriose was obtained for ten days and the half-life was about 15 days. In a continuous reaction using immobilized multienzyme, starch was completely converted into maltose at 50°C and at a space velocity of 1.2, a comparative longer half-life (20 days) was obtained. It was concluded that starch was smoothly converted into maltose with the aid of α-amylase contaminated in the immobilized pullulanase and the operational stability of the column increased with 2-5mM Ca²⁺.     

Catalytic properties of the immobilized Talaromyces thermophilus β-xylosidase and its use for xylose and xylooligosaccharides production

The present study explores the efficiency of Talaromyces thermophilus β-xylosidase, in the production of xylose and xylooligosaccharides. The β-xylosidase was immobilized by different methods namely ionic binding, entrapment and covalent coupling and using various carriers. Chitosan, pre-treated with glutaraldehyde, was selected as the best support material for β-xylosidase immobilization; it gave the highest immobilization and activity yields (94%, 87%, respectively) of initial activity, and also provided the highest stability, retaining 94% of its initial activity even after being recycled 25 times. Shifts in the optimal temperature and pH were observed for the immobilized β-xylosidase when compared to the free enzyme. The maximal activity obtained for the immobilized enzyme was achieved at pH 8.0 and 53 °C, whereas that for the free enzyme was obtained at pH 7.0 and 50 °C. The immobilized enzyme was more thermostable than the free β-xylosidase. We observed an increase of the K_m values of the free enzyme from 2.37 to 3.42 mM at the immobilized state. Native and immobilized β-xylosidase were found to be stimulated by Ca²⁺, Mn²⁺ and Co²⁺ and to be inhibited by Zn²⁺, Cu²⁺, Hg²⁺, Fe²⁺, EDTA and SDS. Immobilized enzyme was found to catalyze the reverse hydrolysis reaction, forming xylooligosaccharides in the presence of a high concentration of xylose. In order to examine the synergistic action of xylanase and β-xylosidase of T. thermophilus, these two enzymes were co-immobilized on chitosan. A continuous hydrolysis of 3% Oat spelt xylan at 50 °C was performed and better hydrolysis yields and higher amount of xylose was obtained.     

Use of co-immobilized beta-amylase and pullulanase in reduction of saccharification time of starch and increase in maltose yield

Beta-amylase and pullulanase were co-immobilized to poly(acrylamide-acrylic acid) resin [P(AAm-AAc)] using 1-ethyl-3-(3-dimethylaminopropyl) carbodimide hydrochloride (EDC). The combined beta-amylase and pullulanase activity was 32% relative to the nonimmobilized beta-amylase. Co-immobilization of beta-amylase and pullulanase increased the maltose yield compared to thart of the immobilized beta-amylase alone and reduced the saccharification time to about 50 h. The results showed that there is a significant increase in the thermal stability, pH stability, and stability toward gamma irradiation. The results also suggest that the co-immobilization of beta-amylase and pullulanase is a potentially useful approach for commercial starch hydrolysis.     

Enhancement of starch conversion efficiency with free and immobilized pullulanase and alpha-1,4-glucosidase

Glucoamylase and pullulanase were immobilized on reconstituted bovine-hide collagen membranes using the covalent azide linkage method. A pretanning step was incorporated into the immobilization procedure to enable the support matrix to resist proteolytic activity while accommodating an operating temperature of 50 degrees C. The immobilized glucoamylase and pullulanase activities were 0.91 and 0.022 mg dextrose equivalent (DE) min(-1) cm(-2) of membrane, respectively. Immobilized glucoamylase had a half-life of 50 days while the immobilized pullulanase had a half-life of 7 days. This is a considerably improved stability over that reported by other researchers. The enzymes were studied in their free and immobilized forms on a variety of starch substrates including waxy maize, a material which contains 80% alpha-1-6-glucosidic linkages. Substrate concentrations ranged from 1% to a typical commercial concentration of 30%. Conversion efficiencies of 90-92% DE were obtained with free and immobilized glucoamylase preparations. Conversion enhancements of 4-5 mg of DE above this level were obtained by the use of pullulanase in its free or immobilized forms. Close examination of free pullulanase stability as a function of pH indicated improved thermal stability at higher pH values. At 50 degrees C and pH 5.0, the free enzyme was inactivated after 24 h. At pH 7.0, the enzyme still possessed one-half its activity after 72 h. Studies were conducted in both batch and continuous total recycle reactors. All experiments were conducted at 50 degrees C. Experiments conducted with coimmobilized enzymes proved quite promising. Levels of conversion equivalent to those obtained with the individually immobilized enzymes were realized.     

Physiological and enzymatic characterization of a novel pullulan-degrading thermophilic Bacillus strain 3183

Summary A new thermophilic Bacillus strain 3183 (ATCC 49341) was isolated from hot-spring sediments. The organism grew on pullulan as a carbon source and showed optimum pH and temperature at pH 5.5 and 62° C, respectively, for growth. The strain reduced nitrate to nitrite both aerobically and anaerobically. It produced extracellular thermostable pullulanase and saccharidase activities which degraded pullulan and starch into maltotriose, maltose, and glucose. Medium growth conditions for pullulanase production were optimized. The optimum pH and temperature for pullulanase activity were at pH 6.0 and 75° C, respectively. The enzyme was stable at pH 5.5-7.0 and temperature up to 70° C in the absence of substrate. The K _m for pullulan at pH 6.0 and 75° C was 0.4 mg/ml. The pullulanase activity was stimulated and stabilized by Ca²⁺. It was inhibited by ethylenediaminetetraacetate (EDTA), beta and gamma-cyclodextrins but not by alpha-cyclodextrin and reagents that inhibit essential enzyme SH-groups. Offprint requests to: B. C. Saha     

Purification and properties of a thermoactive and thermostable pullulanase from Thermococcushydrothermalis, a hyperthermophilic archaeon isolated from a deep-sea hydrothermal vent

The extremely thermophilic archaeon Thermococcus hydrothermalis, isolated from a deep-sea hydrothermal vent in the East Pacific Rise at 21°N, produced an extracellular pullulanase. This enzyme was purified 97-fold to homogeneity from cell-free culture supernatant. The purified pullulanase was composed of a single polypeptide chain having an estimated molecular mass of 110 kDa (gel filtration) or 128 kDa (sodium dodecyl sulfate/polyacryl amide gel electrophoresis). The enzyme showed optimum activity at pH 5.5 and 95 °C. The thermostability and the thermoactivity were considerably increased in the presence of Ca²⁺. The enzyme was activated by 2-mercaptoethanol and dithiothreitol, whereas N-bromosuccinimide and α-cyclodextrin were inhibitors. This enzyme was able to hydrolyze, in addition to the α-1,6-glucosidic linkages in pullulan, α-1,4-glucosidic linkages in amylose and soluble starch, and can therefore be classified as a type II pullulanase or an amylopullulanase. The purified enzyme displayed Michaelis constant (K _m) values of 0.95 mg/ml for pullulan and 3.55 mg/ml for soluble starch without calcium and, in the presence of Ca²⁺, 0.25 mg/ml for pullulan and 1.45 mg/ml for soluble starch. Received: 19 November 1997 / Received revision: 9 March 1998 / Accepted: 14 March 1998     

Optimization of fermentation conditions for the production of ethanol from sago starch by co-immobilized amyloglucosidase and cells of Zymomonas mobilis using response surface methodology

Statistical experimental design was used to optimize the conditions of simultaneous saccharification and fermentation (SSF), viz. temperature, pH and time of fermentation of ethanol from sago starch with co-immobilized amyloglucosidase (AMG) and Zymomonas mobilis MTCC 92 by submerged fermentation. Maximum ethanol concentration of 55.3 g/l was obtained using a starch concentration of 150 g/l. The optimum conditions were found to be a temperature of 32.4 °C, pH of 4.93 and time of fermentation of 17.24 h. Thus, by using SSF process with co-immobilized AMG and Z. mobilis cells MTCC 92, the central composite design (CCD) was found to be the most favourable strategy investigated with respect to ethanol production and enzyme recovery.     

Modified chitosan as a spacer for protein immobilization

Abstract

Three new, water-soluble, N-modified chitosan derivatives containing poly(ethylene glycol), dextran or inulin side chains were used as spacers for enzyme immobilization on a natural silk carrier. Amylolytic enzymes Maltogenase L and Promozyme D2, lipolytic enzyme Resinase HT and a complex of proteolytic enzymes from Streptomyces flavus 197 were immobilized. The activity of the immobilized enzymes and their stability during storage were similar to that obtained with synthetic polyamine—poly(ethylene imine) as a spacer. High operational stability of co-immobilized amylolytic enzymes Maltogenase L and Promozyme D2 in a continuous flow mini-reactor was demonstrated.     

Magnetite-alginate beads for purification of some starch degrading enzymes

Starch degrading enzymes, viz., β-amylase, glucoamylase, and pullulanase, were purified using magnetite-alginate beads. In each case, the enzyme activity was eluted by using 1.0 M maltose. β-Amylase (sweet potato), glucoamylase (Aspergillus niger), and pullulanase (Bacillus acidopullulyticus) from their crude preparations were purified 37-, 31-, and 49-fold with 86, 87, and 95% activity recovery, respectively. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed single band in each case.     

Thermostable Amylolytic Enzymes from a New Clostridium Isolate

A new Clostridium strain was isolated on starch at 60°C. Starch, pullulan, maltotriose, and maltose induced the synthesis of α-amylase and pullulanase, while glucose, ribose, fructose, and lactose did not. The formation of the amylolytic enzymes was dependent on growth and occurred predominantly in the exponential phase. The enzymes were largely cell bound during growth of the organism with 0.5% starch, but an increase of the starch concentration in the growth medium was accompanied by the excretion of α-amylase and pullulanase into the culture broth; but also by a decrease of total activity. α-Amylase, pullulanase, and α-glucosidase were active in a broad temperature range (40 to 85°C) and displayed temperature optima for activity at 60 to 70°C. During incubation with starch under aerobic conditions at 75°C for 2 h, the activity of both enzymes decreased to only 90 or 80%. The apparent K_m values of α-amylase, pullulanase, and α-glucosidase for their corresponding substrates, starch, pullulan, and maltose were 0.35 mg/ml, 0.63 mg/ml, and 25 mM, respectively.     

Characteristic Decrease of Nuclear Protein Kinase Activity in G1-Arrested Cells of Saccharomyces cerevisiae cdc28

An alkalopsychrotrophic strain, Micrococcus sp. 207, inducibly and extracellularly produced amylase and pullulanase. The main hydrolysis product from amylose, with a crude enzyme preparation, was maltotetraose. The optimum temperature for activity of the amylase was 60°C and that for pullulanase 55°C. The activities at 0 to 30°C exhibited similar activation energy values. In an optimized production medium at pH 9.7, the highest yields of these enzymes were obtained after cell growth at 18°C for 4 days. At pH 8.5, the yields of amylase and pullulanase became maximum after 3 days cultivation. With more prolonged cultivation, the yield of amylase but not that of pullulanase activity decreased. These enzymes were not produced at temperatures above 30°C. Sucrose was not effective as an inducer, but it stimulated cell growth and enhanced the enzyme productivities with soluble starch.     

Purification of pullulanase from <Emphasis Type="Italic">Aureobasidium pullulan</Emphasis>s

Purification and characterization of pullulanase from Aureobasidium pullulans. Pullulanase was purified by using gel—filtration column then on ion exchange using Q-sepharose column yielding a single peak. Purification was further carried out on SP-sepharose column. Molecular weight of pullulanase from A. pullulans was found to be about 73 KDa on the SDS-PAGE 10%. Native-PAGE 10% showed the activity of pullulanase, using polyacrylamide gel containing pullulan. Hydrolysis products from pullulanase activity with soluble starch, glycogen and pullulan on thin layer chromatography appeared as one band which is maltotriose, while α-amylase with soluble starch and glycogen showed two bands which are maltose and maltotriose but α-amylase gave negative result with pullulan on TLC chromatography only. Pullulanase could degrade α-1,6 glycosidic linkage of the previous substrates, while amylase could degrade α-1,4 glycosidic linkage of glycogen, soluble starch and pullulan. MALDI-Ms was employed to deduce protein sequence of pullulanase.     

Immobilization of porcine pancreatic <Emphasis Type="Italic">α</Emphasis>-amylase on magnetic Fe<Subscript>2</Subscript>O<Subscript>3</Subscript> nanoparticles: Applications to the hydrolysis of starch

Enzymes play a pivotal role in catalyzing diverse reactions. However, their instability upon repetitive/prolonged use, as well as their inhibition by high substrates and product concentration, remains an area of concern. In this study, porcine pancreatic α-amylase was immobilized on magnetic Fe₂O₃ nanoparticles (Fe₂O₃-NPs) in order to hydrolyze starch. The magnetic nanoparticle bound enzymes retained 94% of their initial enzyme activity. X-ray diffraction and atomic force microscopy analyses showed that the prepared matrix had advantageous microenvironment and a large surface area for binding significant amounts of protein. Functional groups present in enzyme and support were monitored by Fourier transform infrared spectroscopy. Immobilized enzyme exhibited lowered pH optimum (pH 6.0) to a greater degree than its soluble counterpart (pH 7.0). Optimum temperature for the immobilized enzyme shifted towards higher temperatures. The immobilized enzyme was significantly more resistant to inactivation caused by various metal ions and chemical denaturants. Immobilized α-amylase hydrolyzed 92% starch in a batch process, after 8 h at 40°C; while the free enzyme could hydrolyze only 73% starch under similar experimental conditions. A reusability experiment demonstrated that the immobilized enzyme retained 83% of its original activity even after its 8^th repeated use.     

Covalent immobilization of pullulanase on alginate and study of its hydrolysis of pullulan

The immobilization of pullulanase from Klebsiella pneumoniae by grafting was investigated. Pullulanase was linked after activation of alginate via a covalent bond between the amine groups of the enzyme and the carboxylic acid groups of alginate. The immobilization yield was 60%. The activity of free pullulanase and immobilized pullulanase was followed by the quantification of reducing ends by colorimetric assay and the determination of the molar masses of the hydrolyzed pullulan by SEC/MALS/DRI. Compared to free pullulanase, the kinetics is largely slowed. The evolution of the weight average molar mass of pullulan leading to high production of shorter oligosaccharides during hydrolysis is not the same as that obtained with free enzyme. Immobilized pullulanase retained 75% and 30% of its initial activity after 24 h and 14 days of incubation at 60°C, respectively while free pullulanase lost its activity after 5 h of hydrolysis at the same temperature. The kinetic parameters of immobilized pullulanase were also investigated by isothermal titration calorimetry (ITC). The affinity of immobilized enzyme to its substrate was reduced compared to the free pullulanase due to steric hindrance and chemical links. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:883–889, 2015     

General Biochemical Characterization of Thermostable Pullulanase and Glucoamylase from Clostridium thermohydrosulfuricum

Cell extracts of Clostridium thermohydrosulfuricum, an anaerobic bacterium which ferments starch into ethanol at 65°C, contained both pullulanase and glucoamylase activities. The general physiochemical and catalytic properties of these enzyme activities were compared. Pullulanase and glucoamylase activities were stable and optimally active at 85 and 75°C, respectively. The pH optima for activity and pH stability ranges were, respectively, 5.5 to 6 and 4.5 to 5.5 for pullulanase and 4 to 6 and 5 to 6 for glucoamylase. The apparent [S]_0.5v and V_max for pullulanase activity on pullulan were 0.33 mg/ml and 2.6 U/mg of protein. The apparent [S]_0.5v and V_max for glucoamylase activity on starch were of 0.41 mg/ml and 0.31 U/mg of protein. These enzymes were active and stable in the presence of air or 10% (vol/vol) ethanol. These enzyme activities allowed the organism to actively degrade raw starch into glucose in the absence of significant α-amylase activity.     

An enzymic microassay for starch

Abstract Conditions are described for measuring the starch content of plant tissues or extracts as glucose over the range from 10^?7 mol to 10^?14 mol. The method is based on the hydrolysis of gelatinized starch by amyloglucosidase; the glucose released is measured by reduction of NADP⁺ by coupled enzymic reactions. The NADPH is determined directly either spectrophotometrically or fluorimetrically, or after enzymic amplification. Amyloglucosidases were tested for contaminating enzymes which might degrade glucans other than starch, and a commercial preparation from Rhizopus niveus was found to be suitable for use without pretreatments. Glucose present in tissues and extracts may be measured and subtracted from starch values using appropriate blanks, or first destroyed by dilute alkali and heat. Addition of α-amylase to amyloglucosidase during starch hydrolysis was not found to increase percentage hydrolysis from the normal range of 86–99% from starches of different sources. The procedures described are rapid and several orders of magnitude more sensitive than current methods, and can be used to measure the starch content of single cells.     

Immobilized enzyme system for determination of sialic acid in serum or urine.

An immobilized enzyme system has been developed and employed to determine the concentration of sialic acid (N-acetylneuraminic acid) in human serum and urine. Two enzyme pairs, neuramindiase-Neu-5-Ac lyase and pyruvate oxidase-peroxidase, have been respectively co-immobilized onto 1,12-aminododecane-agarose with glutaraldehyde. The relative specific activity of the co-immobilized neuraminidase and Neu-5-Ac lyase were 60% and 78%, and those of pyruvate oxidase and peroxidase were 50% and 95% of the corresponding soluble enzymes, respectively. The optimal reaction pH at 37 degrees C for each of the co-immobilized enzymes was about one pH unit higher than that of the corresponding soluble enzyme. The optimal reaction temperature of each enzyme was increased as a result of immobilization. The thermal stability at 45 degrees C of the immobilized neuraminidase, Neu-5-Ac lyase, pyruvate oxidase, and peroxidase were increased 80-, 83-, 115-, and 147-fold, respectively. Km and Vm of each immobilized and co-immobilized enzyme have also been determined. The system provided a convenient and rapid method to determine the concentration of total sialic acid without pretreatment of the sample. The results correlated satisfactorily with those obtained by using a soluble enzyme system. The co-immobilized enzymes were stable for at least 1 year of 500 tests when used repeatedly. The system is thus a reproducible and reliable novel assay method for sialic acid in the serum or urine sample.     

Immobilization of enzymes based on hydrophobic interaction. II. Preparation and properties of an amyloglucosidase adsorbate

Amyloglucosidase from Aspergillus niger (α-1,4 and 1,6 glucan glucohydrolase, EC 3.2.1.3) was immobilized through adsorption onto a hexyl–Sepharose, containing 0.51 mol hexyl-group per mole of galactose. The adsorption limit of the carrier with respect to this enzyme was about 17 mg per gram wet conjugate. The retention of activity upon immobilization was high, varying from essentially full activity at low enzyme content down to 68% at the adsorption limit. The immobilized preparation, as well as the soluble enzyme, showed apparent zero order kinetics within 60% of the substrate's conversion limit. Product inhibition of the soluble enzyme showed a k₁ of 5 · 10^?2M. In the presence of 3M NaCl, adsorbates were formed more rapidly and with a higher yield of immobilized protein, but with lower specific activity. Conjugates resulting from adsorption of amyloglucosidase in identical concentrations, but at different salt contents, showed comparable activities and operational stabilities. Continuous operation for three months reduced conjugate activity to 40%. The thermal stability of the adsorbate was inferior to that of the soluble enzyme, but was noticeably enhanced in the presence of substrate.