Immobilization of cellulase using acrylamide grafted acrylonitrile copolymer membranes

Immobilization of cellulase onto acrylamide grafted acrylonitrile copolymer (PAN) membranes by means of glutaraldehyde has been studied. The bound cellulase was verified by X-ray photoelectron spectroscopy. The activities of free cellulase and immobilized cellulase are determined by measuring the amount of glucose made from carboxymethyl cellulase in the given conditions. Results show that immobilization conditions had some effects on the activity of immobilized cellulase. The immobilized cellulase had a higher K_m than free cellulase (0.02 mg/ml) did. The immobilized cellulase had better stability with respect to pH or temperature than free cellulase.     

A Study of the Hydrolysis of Waste Paper Cellulose with a Vertically Hanging Immobilized Cellulase Reactor and the Reuse of the Immobilized Cellulase

A commercialized cellulase from Trichoderma reesei has been successfully immobilized by using calcium alginate gel in our laboratory. The waste paper cellulose was hydrolyzed with a special design of the reactor to form a vertically hanging immobilized cellulase under the optimum conditions of pH 4.0 and 45 °C. Glucose, cellobiose and xylose are the major hydrolysis products. The glucose production from the hydrolysis with the vertically hanging immobilized cellulase was about 1.73‐fold better than the freely suspended immobilized cellulase. The average diameter of the immobilized cellulase pellets was 4.190 ± 0.291 mm. UV light irradiation deactivates the activity of the immobilized cellulase. The advantage of the vertically hanging immobilized cellulase reactor is an easy recycle and reuse of the immobilized cellulase. Washing and soaking the recycled immobilized cellulase with distilled water for one day can restore its activity to a small extent. Overall, the application of the hanging immobilized cellulase reactor for waste paper cellulose hydrolysis is successful.     

Cloning and expression of aClostridium thermocellum dna fragment that encodes a protein related to cellulosome component sL

Antibodies raised against the SL subunit of the Clostridium thermocellum cellulosome were used to screen a library of C. thermocellum chromosomal DNA fragments constructed in the vector lambda gt11. A DNA fragment that encoded a polypeptide that crossreacted with the anti-SL antibodies was isolated and its restriction map elucidated. No similarity with other previously cloned DNA fragments has been found. The anti-SL crossreacting polypeptide was isolated from recombinant Escherichia coli and found to have a mol mass of 37,000 Da and to possess low levels of CMCase and Avicelase activity. Using CMC as the substrate, a temperature optimum of 55 degrees C and a pH optimum of 6.6 were observed. These properties were compared to those of C. thermocellum SL isolated by electroelution from an SDS gel, which was also found to possess low levels of CMCase and Avicelase activities. In addition, the SL proteins produced in C. thermocellum and E. coli were able to interact positively against Avicel with an endoglucanase (Ss) purified from the C. thermocellum crude cellulase preparation, and with a recombinant protein that crossreacted with anti-Ss antibodies.     

基于聚乙烯醇/Fe2O3纳米颗粒的纤维素酶固定化

以聚乙烯醇/Fe2O3磁性纳米颗粒为纤维素酶固定化载体, 通过反复冻融的方法成功地实现了纤维素酶固定化. 采用透射电镜、红外光谱仪、振动样品磁强度计对固定化酶复合体进行了表征, 结果显示, 固定化酶复合体为大小约1 μm的微凝胶团, 内含10 nm左右的Fe2O3纳米颗粒. 研究影响固定化因素后发现, 当pH为6, 固定化时间为11 h, 纤维素酶/PVA质量比为4, PVA/Fe质量比为50时, 固定化纤维素酶效果最好. 通过该方法固定后酶活回收率达42%, 酶水解效率显著提高, 经过5次反应后的固定化酶相对酶活力保留50%以上. 因此, 基于聚乙烯醇/Fe2O3纳米颗粒的纤维素酶固定有利于酶的循环使用并显著提高酶的使用效率, 是一种有效固定化纤维素酶的新方法.     

Cascade Enzymatic Hydrolysis Coupling with Ultra ne Grinding Pretreatment for Sugarcane Bagasse Sacchari cation

The biorefinery process for sugarcane bagasse saccharification generally requires significant accessibility of cellulose. We reported a novel method of cascade cellulase enzymatic hydrolysis coupling with ultrafine grinding pretreatment for sugarcane bagasse saccharification. Three enzymatic hydrolysis modes including single cellulase enzymatic hydrolysis, mixed cellulase enzymatic hydrolysis, and cascade cellulase enzymatic hydrolysis were compared. The changes on the functional group and surface morphology of bagasse during cascade cellulase enzymatic hydrolysis were also examined by FT-IR and SEM respectively. The results showed that cascade enzymatic hydrolysis was the most efficient way to enhance the sugarcane bagasse sacchari cation. More than 65% of reducing sugar yield with 90.1% of glucose selectivity was achieved at 50 oC, pH=4.8 for 72 h (1200 r/min) with cellulase I of 7.5 FPU/g substrate and cellulase II of 5 FPU/g substrate.     

Effect of ethanediamine on bio-polishing of cotton fabrics with cellulase

n-Propylamine and n-butylamine showed an inhibitory effect on cellulase A and cellulase B, while ethanediamine displayed a positive effect on both of these cellulases. Relative filter paper activity and relative CMCase activity of cellulase A and cellulase B measured at 50 °C were increased by 16.0 and 25.2 %, and 18.9 and 13.9 %, respectively, by the appearance of ethanediamine at a certain concentration. Also the addition of ethanediamine maintained the thermal stability of cellulase A and B at 65 °C to some extent and showed a stronger stabilizing effect on cellulase A than cellulase B. Third, the addition of ethanediamine within a certain concentration range enhanced the bio-polishing effect of cotton fabric enzymatic treatment at 50 °C to some extent, obtaining a close bio-polishing effect of cotton fabrics treated at 50 °C; the addition of ethanediamine saved some of the dose of cellulase A and B. Last but not least, the appearance of ethanediamine broadened the operating temperature of cellulase A to 65 °C, and it had a less positive effect on cellulase B at 65 °C.     

纤维素酶的二步分离纯化新工艺

 以普通定性滤纸为底物 ,经碱处理后 ,研究其对纤维素酶的亲和吸附作用。结果表明 ,普通定性滤纸对纤维素酶具有比较强的特异性吸附作用 ,能够从粗酶液中分离出纤维素酶 ,再经POROS 2 0HQ阴离子交换柱纯化后即可得到电泳纯的纤维素酶。该法大大简化了传统的纤维素酶纯化工艺 ,所得的纤维素酶活力极高 ,比活达 35 0U/mg以上 ,滤纸一步吸附后纤维素酶的纯化倍数为 9 5 5 ,活性回收率在 10 %左右。纯化后的纤维素酶为内切 β 葡聚糖酶 ,相对分子质量为 6 0 0 0 0 ,最佳 pH为 4 0 ,最佳温度为 70℃。     

Covalent Immobilization of Cellulases onto a Water-Soluble–Insoluble Reversible Polymer

The covalent immobilization of a commercial preparation of cellulase on a reversibly soluble–insoluble enteric polymer Eudragit S-100 by carbodiimide coupling was carried out. The characteristics of covalent Eudragit cellulase were evaluated using Fourier transform infrared (FTIR) spectra, circular dichroism (CD) spectra, and fluorescence spectra. FTIR, CD, and fluorescence measurements also revealed that the cellulases were covalently bonded to the supports. Covalent Eudragit cellulase had binding efficiency of 81.08% which was higher than the noncovalent Eudragit cellulase 56.83%. The relative activity of the native cellulase and covalent Eudragit cellulase increased and reached the maximum (at pH 5.0, 50°C) and then decreased with further increases in pH and temperature. The covalent Eudragit cellulase shows higher stability especially at higher pH and temperature. The K _m value of covalent Eudragit cellulase (4.78 g·L⁻¹) was decreased compared to that of the native cellulase (2.89 g·L⁻¹). The affinity of the cellulase to its substrate was increased when it was immobilized on Eudragit S-100.     

Enhancing cellulase foam fractionation with addition of surfactant

Foam fractionation cannot be used to recover cellulase from an aerated water solution effectively because cellulase by itself can produce only a small amount of foam. The addition of a surfactant can, however, increase the foamate volume and enhance the concentration of cellulase. We studied three detergents individually added to a 200 mg/L cellulase solution to promote foaming. These detergents were anionic, cationic, and nonionic surfactants, respectively. Although contributing to foam production, it was observed that nonionic surfactant (Pluronic F-68) barely concentrated cellulase, leaving the enrichment ratio unchanged, near 1. With anionic surfactant, sodium dedecyl sulfate, and cationic surfactant, cetyltrimethylammonium bromide (CTAB), the enrichment ratio became much larger, but cellulase denaturation occurred, reducing the activity of the enzyme. When CTAB was used to help foam cellulase, β-cyclodextrin was subsequently added to the foamate to help restore the enzyme activity.     

纤维素酶降解纤维素机理的研究

纤维素是自然界中含量最多的一类碳水化合物,同时它也是地球上数量最大的可再生资源。纤维素酶是一种高活性生物催化剂,在纤维素类资源的利用方面发挥重要的作用。本文综述了纤维素、纤维素酶的分子结构和纤维素酶对纤维素的降解机理,影响酶解的主要因素以及提高酶解效率的主要措施,并对纤维素酶研究存在的问题以及今后的发展作了进一步展望。     

A Novel Stepwise Recovery Strategy of Cellulase Adsorbed to the Residual Substrate after Hydrolysis of Steam Exploded Wheat Straw

Cellulase distribution between residual substrate and supernatant in the process of enzymatic hydrolysis of steam-exploded wheat straw was investigated. Subsequently, a novel stepwise recovery strategy with three successive steps was adopted to recover cellulase adsorbed to the residual substrate. The results showed that cellulase protein in the supernatant increased as the hydrolysis time increased. When hydrolysis ended, the cellulase remaining on the residual substrate accounted for 33–42% of the original added cellulase according to the different cellulase loading. To obtain the maximum cellulase recovery rate, the residual substrate was dealt with in three successive steps: washed with sodium acetate buffer (step 1), shaken with sodium acetate buffer (step 2), and then treated with 0.0015 mol/L, pH 10 Ca(OH)₂ (step 3). The total cellulase protein recovered by the three steps reached 96.70–98.14%. The enzyme activity of cellulase recovered by the first two steps was kept well. The ratios of the specific activity between the recovered cellulase and the original were 89–96%, which was by far higher than that using step 3 (the value was 48% ∼ 56%).     

Facile route to enzyme immobilization: core-shell nanoenzyme particles consisting of well-defined poly(methyl methacrylate) cores and cellulase shells

A one-step method for preparing cellulase-immobilized nanoparticles that consist of well-defined poly(methyl methacrylate) (PMMA) cores and cellulase shells has been developed. The core-shell nanoparticles are synthesized from a direct graft copolymerization of methyl methacrylate (MMA) from cellulase in an aqueous medium. Particle formation strongly depends on the surface nature of the cellulase (e.g., pH of reaction media) and MMA to cellulase weight ratio. Under optimized conditions, high MMA conversions (>90%) were achieved, and the PMMA-cellulase nanoparticles produced were very stable with narrow size distributions ( Dv/Dn < 1.20). Particle sizes in the range between 80 and 124 nm (volume average diameter) could be tailored by a variation of cellulase concentration. Transmission electron microscopy micrographs revealed that the nanoparticle had a well-defined PMMA core which was evenly coated with cellulase shell. Study of cellulase activity of the PMMA-cellulase nanoparticles indicated that even though activity of immobilized cellulase on the nanoparticles was 41% less than that of the native cellulase after the polymerization, the immobilized cellulase showed improved properties such as broader working pH range and better thermal stability. Other important advantages of this approach include that the PMMA-cellulase nanoparticles could be produced in high concentrations (up to 18% w/w solids content) and the nanoparticles have thick and evenly distributed enzyme shells. Thus, this method may provide a new commercially viable route to the immobilization of thermally stable enzyme to form nanoenzyme particles.     

提高纤维素酶水解效率和降低水解成本

在我国可大量转化乙醇的是纤维质材料。纤维质材料转化乙醇的关键问题是纤维质转化为糖的过程,提高纤维素酶转化效率的方法有:(1)对纤维质材料进行预处理;(2)研究纤维素酶的最适作用条件;(3)纤维素酶的重复利用;(4)合理的发酵工艺等。本文分析了纤维素的结构以及纤维素酶的作用方式,总结了目前研究较多的几种纤维质材料预处理方法,及其对纤维素酶水解率的影响,并对研究纤维素酶的最适作用条件、纤维素酶的重复利用以及合理的发酵工艺进行了综述和分析。     

Cellulase Production Under Solid-State Fermentation by Trichoderma reesei RUT C30: Statistical Optimization of Process Parameters

Sugar cane bagasse was used as substrate for cellulase production using Trichoderma reesei RUT C30, and the culture parameters were optimized for enhancing cellulase yield. The culture parameters, such as incubation temperature, duration of incubation, and inducer concentration, were optimized for enhancing cellulase yield using a Box-Behnken experimental design. The optimal level of each parameter for maximum cellulase production by the fungus was determined. Predicted results showed that cellulase production was highest (25.6 FPAase units per gram dry substrate) when the inducer concentration was 0.331 ml/gds, and the incubation temperature and time were 33 degrees C and 67 h, respectively. Crude inducer generated by cellulase action was found to be very effective in inducing cellulases. Validation of predicted results was done, and the experimental values correlated well with that of the predicted.     

Inhibition Performance of Lignocellulose Degradation Products on Industrial Cellulase Enzymes During Cellulose Hydrolysis

This study examined the inhibition performance by the major lignocellulose degradation products, including organic acids, furan derivatives, lignin derivatives, and ethanol, on a broadly used commercial cellulase enzyme Spezyme CP (Genencor International, Rochester, NY, USA) to cellulose hydrolysis at both the well-mixing state (shaking flask) and the static state (test tube). The cellulase activity in the cellulase complex of Spezyme CP was assumed to be one single “cellulase”, and the apparent kinetic parameters of this cellulase enzyme were measured as an approximate index of the inhibitory effect to the industrial cellulase enzyme. The inhibition performance of these degradation products was compared and analyzed using the determined apparent kinetic parameters. All the degradation products strongly inhibit the cellulose hydrolysis by cellulase enzyme, and the inhibitions on cellulase were all competitive type. The order of the inhibition strength by the lignocellulose degradation products to cellulase is lignin derivatives > furan derivatives > organic acids > ethanol. This study gave a quantitative view to the enzymatic hydrolysis of lignocellulose under the inhibition performance of the lignocellulose degradation products and will help to understand the lignocellulose recalcitrance to enzyme hydrolysis.     

金银花中绿原酸的酶法提取工艺优化

采用酶法优化提取金银花中的绿原酸,考察纤维素酶酶的用量、酶解时间、酶解温度及回流提取温度对绿原酸含量的影响;用高效液相色谱法(HPLC)测定绿原酸含量。用纤维素酶法提取金银花可提高绿原酸得率。酶法提取最佳条件为:加入纤维素酶3.0%,在46℃下酶解4 h,再在56℃下浸提1 h;其绿原酸含量为3.57%。     

聚甲基丙烯酸-聚乙烯吡啶复合物固定纤维素酶的研究

<正> 作为植物细胞壁主要成份的纤维素,占植物总重的一半,是地球上最丰富的有机物,是对人类有用而且潜力很大的自然资源。将这些廉价易得的纤维素利用纤维素酶转变成葡萄糖,不仅在食品工业上有现实意义,而且对未来化学工业的发展有着不可估量的影响。但由于酶在水溶液中不稳定,反应后难以分离和回收,只能使用一次,成本较高,使其应用受到一定的限制,固定酶的发展正好弥补了上述不足。     

Controlled adsorption of cellulase onto pretreated corncob by pH adjustment

The effective recycling of cellulase requires an in-depth understanding of cellulase adsorption and desorption. In the present study, we examined the adsorption behaviors and stabilities of cellulase at different pH values. Acidic pH (<4.8) was found to favor adsorption, whereas neutral and alkaline pH (especially pH 7 and 10) favored desorption. The influence of pH on cellulase activity was temperature dependent. Under mild conditions (e.g., pH 7 and 25 °C), the effect of pH on cellulase activity was reversible, and the cellulase activity can return to almost 100% by adjusting the pH value to 4.8. However, under severe conditions (e.g. pH 10 and 50 °C), irreversible inactivation may take place. We also explored the roles of pH and temperature in cellulase adsorption kinetics and isotherms. At pH 4.8, temperature had no remarkable effect on the adsorption capacity of the cellulases onto substrate. However, at pH 7 and 10, high temperatures lead to more cellulase desorption. Only at pH 4.8 does cellulase adsorption well fit (R ² > 0.96) the pseudo-first-order kinetic and Langmuir adsorption isotherm (R ² > 0.99) models.     

Determination of cellulase colocalization on cellulose fiber with quantitative FRET measured by acceptor photobleaching and spectrally unmixing fluorescence microscopy

The determination of cellulase distribution on the surface of cellulose fiber is an important parameter to understand when determining the interaction between cellulase and cellulose and/or the cooperation of different types of cellulases during the enzymatic hydrolysis of cellulose. In this communication, a strategy is presented to quantitatively determine the cellulase colocalization using the fluorescence resonance energy transfer (FRET) methodology, which is based on acceptor photobleaching and spectrally unmixing fluorescence microscopy. FRET monitoring of cellulase colocalization was achieved by labeling cellulases with an appropriate pair of FRET dyes and by adopting an appropriate FRET model. We describe here that the adapted acceptor photobleaching FRET method can be successfully used to quantify cellulase colocalization regarding their binding to a cellulose fiber at a resolution <10 nm. This developed quantitative FRET method is promising for further studying the interactions between cellulase and cellulose and between different types of cellulases.     

Bioconversion potential of Trichoderma viride HN1 cellulase for a lignocellulosic biomass Saccharum spontaneum

The industrialisation of lignocellulose conversion is impeded by expensive cellulase enzymes required for saccharification in bioethanol production. Current research undertakes cellulase production from pretreated Saccharum spontaneum through Trichoderma viride HN1 under submerged fermentation conditions. Pretreatment of substrate with 2% NaOH resulted in 88% delignification. Maximum cellulase production (2603 ± 16.39 U/mL/min carboxymethyl cellulase and 1393 ± 25.55 U/mL/min FPase) was achieved at 6% substrate at pH 5.0, with 5% inoculum, incubated at 35°C for 120 h of fermentation period. Addition of surfactant, Tween 80 and metal ion Mn⁺², significantly enhanced cellulase yield. This study accounts proficient cellulase yield through process optimisation by exploiting cheaper substrate to escalate their commercial endeavour.