Enzymatic degradation of residual non-cellulosic polysaccharides present on dew-retted flax fibres

Summary A mixture of Pectional AC and Ultrazym, and enzyme extracted from cultures of Ceraceomyces sublaevis was the most suitable enzyme preparation for depolymerising non-cellulosic materials present on dew-retted fibre at 45°C. All the enzyme treated roves produced high quality yarns compared with the yarns spun from untreated roves. Fludity of all the yarns spun from enzyme treated roves was low, suggesting that the enzymes have not affected the cellulose fibres. The use of polysaccharide-degrading enzymes for the removal of non-cellulosic material present on flax fibre may be more energy efficient than traditional caustic boil treatment (using NaOH) for removing residual non-cellulosic polysaccharides.     

Purification and characterization of intracellular and extracellular α‐glucosidases from Geobacillus toebii strain E134

Two different α‐glucosidase‐producing thermophilic E134 strains were isolated from a hot spring in Kozakli, Turkey. Based on the phenotypic, phylogenetic and chemotaxonomic evidence, the strain was proposed to be a species of G. toebii. Its thermostable exo‐α‐1,4‐glucosidases also were characterized and compared, which were purified from the intracellular and extracellular fractions with estimated molecular weights of 65 and 45 kDa. The intracellular and extracellular α‐glucosidases showed optimal activity at 65 °C, pH 7·0, and at 70 °C, pH 6·8, with 3·65 and 0·83 K_m values for the pNPG substrate, respectively. Both enzymes remained active over temperature and pH ranges of 35–70 °C and 4·5–11·0. They retained 82 and 84% of their activities when incubated at 60 °C for 5 h. Their relative activities were 45–75% and 45–60% at pH 4·5 and 11·0 values for 15 h at 35 °C. They could hydrolyse the α‐1,3 and α‐1,4 bonds on substrates in addition to a high transglycosylation activity, although the intracellular enzyme had more affinity to the substrates both in hydrolysis and transglycosylation reactions. Furthermore, although sodium dodecyl sulfate behaved as an activator for both of them at 60 °C, urea and ethanol only increased the activity of the extracellular α‐glucosidase. By this study, G. toebii E134 strain was introduced, which might have a potential in biotechnological processes when the conformational stability of its enzymes to heat, pH and denaturants were considered. Copyright © 2011 John Wiley & Sons, Ltd.     

Efficiency of new fungal cellulase systems in boosting enzymatic degradation of barley straw lignocellulose

This study examined the cellulytic effects on steam-pretreated barley straw of cellulose-degrading enzyme systems from the five thermophilic fungi Chaetomium thermophilum, Thielavia terrestris, Thermoascus aurantiacus, Corynascus thermophilus, and Myceliophthora thermophila and from the mesophile Penicillum funiculosum. The catalytic glucose release was compared after treatments with each of the crude enzyme systems when added to a benchmark blend of a commercial cellulase product, Celluclast, derived from Trichoderma reesei and a beta-glucosidase, Novozym 188, from Aspergillus niger. The enzymatic treatments were evaluated in an experimental design template comprising a span of pH (3.5-6.5) and temperature (35-65 degrees C) reaction combinations. The addition to Celluclast + Novozym 188 of low dosages of the crude enzyme systems, corresponding to 10 wt % of the total enzyme protein load, increased the catalytic glucose yields significantly as compared to those obtained with the benchmark Celluclast + Novozyme 188 blend. A comparison of glucose yields obtained on steam-pretreated barley straw and microcrystalline cellulose, Avicel, indicated that the yield improvements were mainly due to the presence of highly active endoglucanase activity/activities in the experimental enzyme preparations. The data demonstrated the feasibility of boosting the widely studied T. reeseicellulase enzyme system with additional enzymatic activity to achieve faster lignocellulose degradation. We conclude that this supplementation strategy appears feasible as a first step in identifying truly promising fungal enzyme sources for fast development of improved, commercially viable, enzyme preparations for lignocellulose degradation.     

Is digestive capacity limiting growth at low temperatures in roach?

In roach Rutilus rutilus growth ceases below a temperature threshold of 12° C. This cessation of growth is accompanied by a reduction in feeding. Do roach decrease feeding in the cold because of reduced energy demand, caused by the decelerating effect of low temperature on metabolism and growth, or is feeding directly limited by low temperatures, leading to reduced growth rates? It was found that at low temperatures the intake and digestion of food may be limited by reduced activities of digestive enzymes. Trypsin, amylase and γ‐glutamyl transferase showed a negative compensation with respect to temperature, resulting in very low activities at acclimation temperatures of ≤12° C. Trypsin activity, falling from 400·5 ± 131·2 U g^?1 fresh mass of the gut at 27° C to 12·5 U g^?1 fresh mass at 4° C, displayed the strongest linear correlation with growth rates, suggesting that trypsin activities may set a limit to growth in the low temperature range. If protein digestion is limiting at low temperatures, this should be reflected in reduced concentrations of amino acid in the white muscle. The size of the total amino acid pool was not affected by temperature acclimation and ranged between 19·2 ± 6·2 and 25·2 ± 3·6 µmol g^?1 fresh mass of the white muscle. A decrease, however, was found of several amino acids, mainly of threonine and glutamine, in the low temperature range. Low concentrations of the essential amino acid threonine (0·14 ± 0·03 µmol g^?1 fresh mass at 12° C and 0·12 ± 0·05 µmol g^?1 fresh mass at 4° C) were probably due to nutritional or digestional limitations and may therefore have resulted from reduced trypsin activity in the cold. The non‐essential amino acid glutamine, however, can be endogenously synthesized and its low level observed at 4° C (0·16 ± 0·09 µmol g^?1 fresh mass) was not necessarily a result of low trypsin activities. It is more likely that low temperatures impair glutamine synthesis. The possibility that glutamine concentrations may be down regulated under conditions when anabolic processes are not advantageous is discussed.     

The retting of flax after preservation with sulphur dioxide

Experiments were carried out to compare the retting of moist flax preserved with sulphur dioxide with that of green dried flax, using whole straw samples. When retted in water at either a constant 20°C or 28°C dried flax was fully retted after 15 and 10 days respectively whereas the sulphur dioxide treated flax (20 g sulphur dioxide kg“¹ flax DM) had undergone almost no retting after 20 days at 20dC or 10 days at 28°C. Pre-soaking the treated flax for 24 h in water and changing the acidified water, raised the pH of the retting liquor to a more normal value but did not significantly increase the rate of retting. Addition of the pectinase enzyme preparation ‘Flaxzyme’ to retting liquor at the rate of either 1.5 g kg^-1 or 3.0 g kg^-1 water, and at a constant temperature of 20°C, substantially increased the rate of retting of both sulphur dioxide treated and dried flax. Optimum degree of retting was achieved at 24 h with the treated flax and at 97 h with the dried flax. Pre-rinsing of the sulphur dioxide treated straw only served to reduce the rate of retting. It was concluded that natural water retting of sulphur dioxide treated flax is retarded by the presence of acidic residues of sulphur dioxide, while enzyme retting is enhanced by these. In further smaller scale experiments using bundles of cut flax straw Flaxzyme was added at concentrations ranging from 0–8.0 ml litre ¹ to containers containing flax in water at ratios from 1:10 to 1: 600 flax:water and the producion of galacturonic acid was used as an indicator of retting progress. Retting took place more rapidly at higher flax to water ratios for a given enzyme concentration. This effect was attributed to the lower pH of higher flax to water ratios which created pH conditions closer to the pH optimum for the retting enzymes. When enzyme retting was compared at a range of buffered pH's the optimum was pH 4.0. At a buffered pH of 4.0 and a temperature of 19°C, retting of sulphur dioxide treated moist flax (flax to water ratio of 1:10) was achieved with Flaxzyme concentrations as low as 0.5 ml litre”‘,much lower than the previously reported minimum of 3.0 ml litre’.     

Production and characterization of ferulic acid esterase activity in crude extracts by Streptomyces avermitilis CECT 3339

Streptomyces avermitilis CECT 3339 produces extracellular ferulic acid esterase (FAE) activity during growth on a range of lignocellulose substrates. Maximal levels of FAE activity were detected in culture filtrates from S. avermitilis CECT 3339 grown in media containing wheat bran and yeast extract as carbon and nitrogen sources respectively. Biochemical characterization of this enzyme activity revealed that it was 100-fold higher when wheat bran was pretreated with Celluclast (a mix of hydrolytic enzymes). FAE was found to be end-product-inhibited. Characterization of the properties of the enzyme showed that FAE exhibited an activity optimum pH at 6 with pH stability between pH 6 and 8. The optimum temperature was 50 °C while the temperature stability was between 30 °C and 40 °C, with rapid inactivation at 60 °C and above. The characteristics and stability of FAE from S. avermitilis CECT 3339 suggest a potential role for this enzyme in combination with endoxylanases for the upgrading of plant-residue silage and for biopulping. Received: 17 November 1997 / Received revision: 13 March 1998 / Accepted: 13 April 1998     

Efficiencies of designed enzyme combinations in releasing arabinose and xylose from wheat arabinoxylan in an industrial ethanol fermentation residue

The generation of a fermentable hydrolysate from arabinoxylan is an important prerequisite for utilization of wheat hemicellulose in production of ethanol or other value added products. This study examined the individual and combined efficiencies of four selected, commercial, multicomponent enzyme preparations Celluclast 1.5 L (from Trichoderma reesei), Finizym (from Aspergillus niger), Ultraflo L (from Humicola insolens), and Viscozyme L (from Aspergillus aculeatus) in catalyzing arabinose and xylose release from water-soluble wheat arabinoxylan in an industrial fermentation residue (still bottoms) in lab scale experiments. Different reaction conditions, i.e. enzyme dosage, reaction time, pH, and temperature, were evaluated in response surface and ternary mixture designs. Ultraflo L treatment gave optimal arabinose release: treatment (6 h, 60 °C, pH 6) with this enzyme preparation liberated up to 46% by weight (wt.%) of the theoretically maximal arabinose yield from the substrate. Celluclast 1.5 L was superior to the other enzyme preparations in releasing xylose and catalyzed release of up to 25 wt.% of the theoretical maximum xylose yield (6 h, 60 °C, pH 4). Prolonged treatment for 24 h with a 50:50 mixture of Celluclast 1.5 L and Ultraflo L at 50 °C, pH 5 exhibited a synergistic effect in xylose release and 62 wt.% of the theoretically maximal xylose yield was achieved. Addition of pure β-xylosidase from T. reesei to the Ultraflo L preparation released the same amounts of xylose from the substrate as the 50:50 mixture of Celluclast 1.5 L and Ultraflo L. The data thus signified that the synergistic effect in xylose release between Celluclast 1.5 L and Ultraflo L is the result of a three-step interaction mechanism involving α-l-arabinofuranosidase and different xylan degrading enzyme activities in the two enzyme preparations.     

Characterization of the novel xylanase from the thermophilic Geobacillus thermodenitrificans JK1

Thermophilic strain JK1 was isolated from compost using xylan as a single carbon source. On the basis of 16S rRNA gene phylogenetic analysis and spo0A gene sequence similarity analysis, strain JK1 was identified as Geobacillus thermodenitrificans strain. During the exponential culture growth, the strain JK1 was found to produce the single xylan degrading enzyme ??45 kDa in size. Xylose was not an inducer of this xylanase. Cloning, expression and characterization of the recombinant xylanase were performed. Xylanase of G. thermodenitrificans JK1 was cellulase-free; pH and temperature optimums were found to be 6.0 and 70°C, respectively. The metal ions Na⁺, K⁺, Ca²⁺, and Co²⁺ showed partial inhibition of the activity, while Mn²⁺ had slight stimulating effect on the enzymatic activity. Recombinant xylanase was thermostable over the temperature range of 55?C70°C. It presented the highest stability after incubation at 55°C for 60 min showing 84% residual activity. 50% residual activity was revealed after incubation at 60°C for 60 min as well as at 65 and 70°C for 30 min. Results of the thermostability experiments showed xylanase of JK1 having quite low thermostability when compared with the respective enzymes of the other geobacilli.     

Optimization of some culture parameters and properties of β-glucosidase and β-xylosidase from Penicillium funiculosum NRRL – 13033

Penicillium funiculosum NRRL 13033 produced β-glucosidase and β-xylosidase activities when grown on wheat straw. The addition of some inducers (individually or in combination) to the fermentation medium were tested for the production of both enzymes. The relation of mycelial bound enzyme to cell free enzyme was studied during incubation period of fermentation. The optimum activity of β-glucosidase and β-xylosidase were found to be in the pH 4.5 using phosphate-citrate buffer at 50°C for 60 min and at 55°C for 40 min respectively. β-Glucosidase lost about 40% of its original activity by heating to 65°C for 60 min, while, β-xylosidase activity was found to be nearly stable with the same treatment. Both enzyme activities were greatly inhibited when 1.0% (w/v) of xylose and glucose were added to the assay mixture.     

Media Formulation using Complex Organic Nutrients for Improved Activity,Productivity, and Yield of Candida rugosa Lipase and Esterase Enzymes

Abstract

Candida rugosa is an excellent source of multiple lipase and esterase enzymes; therefore, it is of technological importance to formulate the medium that provides high activity for each enzyme. In this work, the cultivation medium comprising complex nutrients that provided the highest activity, productivity, and yield of C. rugosa enzymes individually was formulated. Time courses of the extracellular and intracellular lipase and esterase activities of C. rugosa were represented and the role of protease in the cultivation progress was discussed. Urea, soy-peptone, yeast extract, a mixture of soy-peptone and yeast extract, cheese whey, and wheat mill bran were tested for their lipolytic and esterasic activities. Urea provided considerably higher extracellular lipase activity when compared to other nitrogen sources; however, soy-peptone provided the highest extracellular esterase activity. Hazelnut, olive, sesame, soybean, and flax seed oils affected the enzyme activities to different extents related to their fatty acid compositions. Hazelnut oil and olive oil provided the highest extracellular lipase and esterase activities, respectively, whereas sesame oil produced the highest biomass. High C₁₈ and C₁₆ ester contents of vegetable oils promoted high lipase and esterase productions, respectively. A temperature of 30°C yielded the highest extracellular and intracellular lipase and esterase activities; however, 35°C produced the highest biomass.     

Studies on α-amylase production by Bacillus licheniformis MIR-61

An acid α-amylase hyperproducing strain, designated as MIR-61, was isolated in a screening procedure from South American soil samples. MIR-61, a 60°C thermoresistant strain, was identified using 98 biochemical and morphological tests and characterized as Bacillus licheniformis by numerical taxonomy. Batch cultures of B. licheniformis MIR-61 showed extracellular α-amylase and α-glucosidase activities during the exponential growth phase. The production of α-amylase was studied at free and constant pH values at 37 and 45°C. Maximum α-amylase activity (4,767 kU/dm³ in a liquid medium) was detected at 45°C at a constant pH (7.0) in the late exponential phase. The α-amylase production by B. licheniformis MIR-61 is 10 to 300 times higher than the enzyme production reported in strains of the same species. Optimum α-amylase activity was found at 50 to 67°C in an acid pH range from 5.5 to 6.0. These properties would allow its use in starch industry processes.     

Comparison of Penicillium echinulatum and Trichoderma reesei cellulases in relation to their activity against various cellulosic substrates

Penicillium echinulatum has been identified as a potential cellulase producer for bioconversion processes but its cellulase system has never been investigated in detail. In this work, the volumetric activities of P. echinulatum cellulases were determined against filter paper (0.27 U/mL), carboxymethylcellulose (1.53 U/mL), hydroxyethylcellulose (4.68 U/mL), birchwood xylan (3.16 U/mL), oat spelt xylan (3.29 U/mL), Sigmacell type 50 (0.10 U/mL), cellobiose (0.19 U/mL), and p-nitrophenyl-glucopiranoside (0.31 U/mL). These values were then expressed in relation to the amount of protein and compared those of Trichoderma reesei cellulases (Celluclast 1.5L FG, Novozymes). Both enzyme complexes were shown to have similar total cellulase and xylanase activities. Analysis of substrate hydrolysates demonstrated that P. echinulatum enzymes have higher beta-glucosidase activity than Celluclast 1.5L FG, while the latter appears to have greater cellobiohydrolase activity. Unlike Celluclast 1.5L FG, P. echinulatum cellulases had enough beta-glucosidase activity to remove most of the cellobiose produced in hydrolysis experiments. However, Celluclast 1.5L FG became more powerful than P. echinulatum cellulases when supplemented with exogenous beta-glucosidase activity (Novozym 188). Both cellulase complexes displayed the same influence over the degree of polymerization of cellulose, revealing that hydrolyzes were carried out under the typical endo-exo synergism of fungal enzymes.     

Biomass hydrolyzing enzymes from plant pathogen Xanthomonas axonopodis pv. punicae: optimizing production and characterization

Xanthomonas axonopodis pv. punicae strain—a potent plant pathogen that causes blight disease in pomegranate—was screened for cellulolytic and xylanolytic enzyme production. This strain produced endo-β-1,4-glucanase, filter paper lyase activity (FPA), β-glucosidase and xylanase activities. Enzyme production was optimized with respect to major nutrient sources like carbon and nitrogen. Carboxy methyl cellulose (CMC) was a better inducer for FPA, CMCase and xylanase production, while starch was found to be best for cellobiase. Soybean meal/yeast extract at 0.5 % were better nitrogen sources for both cellulolytic and xylanolytic enzyme production while cellobiase and xylanase production was higher with peptone. Surfactants had no significant effect on levels of extracellular cellulases and xylanases. A temperature of 28 °C and pH 6–8 were optimum for production of enzyme activities. Growth under optimized conditions resulted in increases in different enzyme activities of around 1.72- to 5-fold. Physico-chemical characterization of enzymes showed that they were active over broad range of pH 4–8 with an optimum at 8. Cellulolytic enzymes showed a temperature optimum at around 55 °C while xylanase had highest activity at 45 °C. Heat treatment of enzyme extract at 75 °C for 1 h showed that xylanase activity was more stable than cellulolytic activities. Xanthomonas enzyme extracts were able to act on biologically pretreated paddy straw to release reducing sugars, and the amount of reducing sugars increased with incubation time. Thus, the enzymes produced by X. axonopodis pv. punicae are more versatile and resilient with respect to their activity at different pH and temperature. These enzymes can be overproduced and find application in different industries including food, pulp and paper and biorefineries for conversion of lignocellulosic biomass.     

来源于葡萄球菌的N-乙酰神经氨酸裂合酶的基因克隆及性质

葡萄球菌Staphylococcus hominis来源的N-乙酰神经氨酸裂合酶基因shnal(GenBank Accession No.EFS20452.1)构建至pET-28a质粒并在大肠杆菌中得到表达.通过目的蛋白的纯化和酶学性质研究发现,ShNAL是一个四聚体,裂解方向的最适反应pH为8.0;合成方向的最适反应pH为7.5,最适反应温度为45℃.在45℃下孵育2h对ShNAL的活力基本无影响,高于45℃时,活力迅速下降.该酶在pH 5.0～10.0的环境中比较稳定,4℃下放置24 h酶的残余活力在70％以上.ShNAL对N-乙酰神经氨酸(Neu5Ac)、N-乙酰甘露糖胺(Man)和丙酮酸(Pyr)的Km值分别是(4.0±0.2) mmol/L、(131.7±12.1)mmol/L和(35.14±3.2) mmol/L,kcat/Km值分别为1.9 L/(mmol·s)、0.08 L/(mmol·s)和0.08 L/(mmol·s).     

Heat-Moisture Treatment of Cereal Starch Observed by X-ray Diffraction

Chitinases I and II were purified from the culture supernatant of Aeromonas sp. 10S-24 by ammonium sulfate precipitation, SP-Sephadex C-50 chromatography, Sephacryl S-200 gel filtration, and chromatofocusing. Both enzymes were most active at pH 4.0 and the optimum temperature for I and II were 50°C and 60°C. Chitinase I was stable at pHs between 4 and 9 and at temperatures below 50°C and chitinase II was stable at pHs between 5 and 7 and at temperatures below 45°C. The molecular weights were estimated by 8D8 polyacrylamide gel electrophoresis to be 112,000 and 115,000 for I and II respectively, while gel filtration showed the molecular weight to be 114,000 for both types of the enzyme. The pIs for I and II were 7.9 and 8.1, respectively. The activities of both enzymes were inhibited by Ag⁺ and iodoacetic acid.     

PURIFICATION AND CHARACTERIZATION OF MUTANASE PRODUCED BY Paenibacillus curdlanolyticus MP-1

Mutanases are enzymes that catalyze hydrolysis of α-1,3-glucosidic bonds in various α-glucans. One of such glucans, mutan, which is synthesized by cariogenic streptococci, is a major virulence factor for induction of dental caries. This means that mutan-degrading enzymes have potential in caries prophylaxis. In this study, we report the purification, characterization, and partial amino acid sequence of extracellular mutanase produced by the MP-1 strain of Paenibacillus curdlanolyticus, bacterium isolated from soil. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of the purified enzyme showed a single protein band of molecular mass 134 kD, while native gel filtration chromatography confirmed that the enzyme was a monomer of 142 kD. Mutanase showed a pH optimum in the range from pH 5.5 to 6.5 and a temperature optimum around 40–45°C. It was thermostable up to 45°C, and retained 50% activity after 1 hr at 50°C. The enzyme was fully stable at a pH range of 4 to 10. The enzyme activity was stimulated by the addition of Tween 20, Tween 80, and Ca²⁺, but it was significantly inhibited by Hg²⁺, Ag⁺, and Fe²⁺, and also by p-chloromercuribenzoate, iodoacetamide, and ethylenediamine tetraacetic acid (EDTA). Mutanase preparation preferentially catalyzed the hydrolysis of various streptococcal mutans and fungal α-1,3-glucans. It also showed binding activity to insoluble α-1,3-glucans. The N-terminal amino acid sequence was NH₂-Ala-Gly-Gly-Thr-Asn-Leu-Ala-Leu-Gly-Lys-Asn-Val-Thr-Ala-Ser-Gly-Gln. This sequence indicated an analogy of the enzyme to α-1,3-glucanases from other Paenibacillus and Bacillus species.     

Engineering chimeric thermostable GH7 cellobiohydrolases in Saccharomyces cerevisiae

We report here the effect of adding different types of carbohydrate-binding modules (CBM) to a single-module GH7 family cellobiohydrolase Cel7A from a thermophilic fungus Talaromyces emersonii (TeCel7A). Both bacterial and fungal CBMs derived from families 1, 2 and 3, all reported to bind to crystalline cellulose, were used. Chimeric cellobiohydrolases with an additional S–S bridge in the catalytic module of TeCel7A were also made. All the fusion proteins were secreted in active form and in good yields by Saccharomyces cerevisiae. The purified chimeric enzymes bound to cellulose clearly better than the catalytic module alone and demonstrated high thermal stability, having unfolding temperatures (T _m) ranging from 72 °C to 77 °C. The highest activity enhancement on microcrystalline cellulose could be gained by a fusion with a bacterial CBM3 derived from Clostridium thermocellum cellulosomal-scaffolding protein CipA. The two CBM3 fusion enzymes tested were more active than the reference enzyme Trichoderma reesei Cel7A both at moderate (45 °C and 55 °C) and at high temperatures (60 °C and 65 °C), the hydrolysis yields being two- to three-fold better at 60 °C, and six- to seven-fold better at 65 °C. The best enzyme variant was also tested on a lignocellulosic feedstock hydrolysis, which demonstrated its potency in biomass hydrolysis even at 70 °C.     

Characterization of chitinase from Streptomyces luridiscabiei U05 and its antagonist potential against fungal plant pathogens

Streptomyces luridiscabiei U05 was isolated from wheat rhizosphere. It produced chitinase, which showed in vitro antifungal properties. The crude enzyme inhibited the growth of Alternaria alternata, Fusarium oxysporum, F. solani, Botrytis cinerea, F. culmorum and Penicillium verrucosum. The chitinase enzyme of the molecular weight of 45 kDa was purified using affinity chromatography of chitin. Streptomyces luridiscabiei U05 produced different chitinolytic enzymes. The highest enzyme activity was observed with the use of 4‐MU‐(GlcNAc)_, which points to the presence of an β‐N‐acetylhexosaminidase. The optimum activity was obtained at 35–40°C and pH 7–8. The enzyme showed thermostability at 35–40°C during 240 min of preincubation and lost its activity at 50°C and 60°C in 60 min. The chitinase activity from S. luridiscabei U05 was strongly inhibited by Hg²⁺ and Pb²⁺ ions, and sodium dodecyl sulphate (SDS). The Ca²⁺, Cu²⁺ and Mg²⁺ ions stimulated the activity of the enzyme.     

Production, characterization and properties of polysaccharide depolymerizing enzymes from a strain ofCurvularia inaequalis

Xylanase, β-glucosidase, β-xylosidase, endoglucanase and polygalacturonase production fromCurvularia inaequalis was carried out by means of solid-state and submerged fermentation using different carbon sources. β-Glucosidase. β-xylosidase, polygalacturonase and xylanase produced by the microorganisms were characterized. β-Glucosidase presented optimum activity at pH 5.5 whereas xylanase, poly-galacturonase and β-xylosidase activities were optimal at pH 5.0. Maximal activity of β-glucosidase was determined at 60°C, β-xylosidase at 70°C, and polygalacturonase and xylanase at 55°C. These enzymes were stable at acidic to neutral pH and at 40–45 °C. The crude enzyme solution was studied for the hydrolysis of agricultural residues.     

Thermostabilization of Candida antarctica lipase B by double immobilization: Adsorption on a macroporous polyacrylate carrier and R1 silaffin-mediated biosilicification

A large improvement in the thermostability of Candida antarctica lipase B (CALB) was achieved through double immobilization, i.e., physical adsorption and R1 silaffin-mediated biosilicification. The C-terminus of CALB was fused with the R1 silaffin peptide for biosilicification. The CALB-R1 fusion protein was adsorbed onto a macroporous polyacrylate carrier and then subsequently biosilicified with tetramethyl orthosilicate (TMOS). After R1 silaffin-mediated biosilicification, the double-immobilized CALB-R1 exhibited remarkable thermostability. The T₅₀⁶⁰ of the double-immobilized CALB-R1 increased dramatically from 45 to 72 °C and that was 27, 13.8, 9.8 and 9.9 °C higher than the T₅₀⁶⁰ values of free CALB-R1, CALB-R1 adsorbed onto a resin, commercial Novozym 435, and Novozym 435 treated with TMOS, respectively. In addition, the time required for the residual activity to be reduced to half (t_1/2) of the double immobilized CALB-R1 elevated from 12.2 to 385 min, which is over 30 times longer life time compared free CALB-R1. The optimum pH for biosilicification was determined to be 5.0, and the double-immobilized enzyme showed much better reusability than the physically adsorbed enzyme even after 6 repeated reuses. This R1-mediated biosilicification approach for CALB thermostabilization is a good basis for the thermostabilization of industrial enzymes that are only minimally stabilized by protein engineering.