Immobilization of Exo-maltotetraohydrolase and Pullulanase

A dual enzyme system of exo-maltotetraohydrolase [EC 3.2.1.60] and pullulanase [EC 3.2.1.41] was studied for the continuous production of maltotetraose. Porous chitosan beads were selected from among many carriers as the best carrier to immobilize both enzymes.

The properties of the immobilized enzymes were examined and compared with those of the native enzymes. For exo-maltotetraohydrolase, the optimum pH of the immobilized enzyme shifted slightly to the acidic side and the pH stability was improved on the alkaline side. The optimum temperature of the immobilized enzyme increased by about 15°C and thermostability was improved by about 10°C. As for pullulanase, very little difference in thermostability was observed.

The effects of operating conditions on the continuous production of maltotetraose using exo- maltotetraohydrolase immobilized on the porous chitosan beads were examined. Porous chitosan beads were recognized to be superior to Diaion HP-50.

The continuous production of maltotetraose was accomplished using the dual immobilized enzyme system. The dual enzyme system proved to be effective to increase the maltotetraose content in the product. A stable operation was successfully continued for more than 60 days.     

A Thermostable Xylanase from a Thermophilic Acidophilic Bacillus sp.

Bacillus sp. 11-IS, a strain of thermophilic acidophilic bacteria, produced an extracellular xylanase during growth on xylan. The enzyme purified from the culture supernatant solution was homogeneous on disc-gel electrophoresis. The molecular weight was calculated to be 56,000 by SDS-gel electrophoresis. The enzyme had a pH optimum for activity at 4.0, and its stability range was pH 2.0 ~ 6.0. The temperature optimum was 80°C (10-min assay); however, the enzyme retained full activity after incubation at 70°C for 15 min. The enzyme acted on carboxymethyl cellulose (CMC) and cellulose, as well as on xylan. The Michaelis constants for larchwood xylan and CMC were calculated to be 1.68 mg xylose eq/ml and 0.465 mg glucose eq/ml, respectively. The predominant hydrolysis products from larchwood xylan were xylobiose, xylotriose, and xylose; the release of arabinose from rice-straw arabinoxylan was not detected. CMC was cleaved to cellobiose and larger oligosaccharides. Thus, the enzyme is considered to be an endoenzyme which degrades the β-1,4-glycosyl linkages in xylan and cellulose.     

Preparation of lysozyme immobilized on textile carriers and its use in treating suppurative wounds

Immobilized forms of lysozyme were prepared by its covalent binding on dialdehyde cellulose and polycaproamide fibres as woven and knitted fabrics respectively. The preparations were estimated by the content of protein and bacteriolytic activity. The lysozyme activity per 1 g of the carrier and the protein content on dialdehyde cellulose were several times higher than those on polycaproamide while the specific activity of lysozyme on the polycaproamide carrier was somewhat higher than that on dialdehyde cellulose. The effect of the immobilized lysozyme in treatment of purulent wounds was studied on albino rats. It was shown that the periods of the wound healing with the use of the immobilized lysozyme were shorter than those with the use of native lysozyme. Cytological and morphological investigation of the wound wall confirmed the higher efficacy of the lysozyme immobilized forms in treatment of purulent wounds as compared to the use of the native enzyme.     

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.     

Growth of Cellulomonas sp. ATCC 21399 on different polysaccharides as sole carbon source Induction of extracellular enzymes

Summary Growth and extracellular enzyme production of Cellulomonas sp. ATCC 21399 on carboxymethylcellulose (CMC), microcrystalline cellulose (Avicel), xylan, galactomannan and starch were compared. The bacteria grew poorly on CMC, whereas high cell densities were obtained on the other substrates. Growth on Avicel resulted in extracellular enzyme activities against CMC, Avicel, xylan, galactomannan and amylose. By contrast, growth on xylan, galactomannan and starch induced only the enzymes neccessary for the degradation of the growth substrate. Extracellular proteinase activity could be measured during growth on all substrates but CMC, and the possibility of proteolytic inactivation of some of the unstable enzymes (i.e. Avicelase and amylase) in discussed.     

Immobilized d-Amino Acid Oxidase Preparation,Some Enzymatic Properties,and Potential Uses

Immobilization of d-amino acid oxidase was investigated by covalently binding the enzyme to cyanogen bromide activated polysaccharides. Among polysaccharides tested, Sepharose 6B was found to be the best carrier.

Some enzymatic properties of the immobilized enzyme were investigated and compared with those of the native enzyme. The optimum pH of the immobilized enzyme was shifted by 0.5 pH units to the acid side in comparison with that of the native enzyme. With regard to substrate specificity, heat stability and effect of temperature, no significant differences were observed between the immobilized and native enzymes.

The immobilized enzyme was conveniently used for a determination of d-amino acids and an analysis of optical purity of l-amino acids.     

Enzyme immobilization via monoclonal antibodies I. Preparation of a highly active immobilized carboxypeptidase A

A novel method for the preparation of highly active immobilized enzymes is described. It is based on the binding of enzymes to suitable carriers via monoclonal antibodies, which bind to the enzyme with high affinity without affecting its catalytic activity. The applicability of the method forwarded has been illustrated by the preparation of two samples of highly active immobilized carboxypeptidase A (CPA) preparations as follows: A mouse monoclonal antibody (mAb 100)to CPA that binds to the enzyme with a high-affinity constant without affecting its catalytic activity was prepared, purified, and characterized. Covalent binding of this monoclonal antibody to Eupergit C (EC) or noncovalent binding to Sepharose-protein A (SPA)yielded the conjugated carriers EC-mAb and SPA.mAb, respectively, which reacted specifically with CPA to give the immobilized enzyme preparations EC-mAb.CPA and SPA.mAb.CPA displaying full catalytic activity and improved stability. At pH 7.5 and a temperature range of 4-37 degrees C an apparent binding constant of approximately 10(8)M(-1) characterizing the interaction of CPA with EC-mAb and SPA.mAb, was obtained. To compare the properties of EC-mAb.CPA and SPA.mAb.CPA with those of immobilized CPA preparations obtained by some representative techniques of covalent binding of the enzyme with a corresponding carrier, the following immobilized CPA preparations were obtained and their properties investigated: EC-CPA (I), a preparation obtained by direct binding of EC with CPA; EC-NH-GA-CPA (II), a derivative obtained by covalent binding of CPA to aminated EC via glutaraldehyde; EC-NH-Su-CPA (III), a CPA derivative obtained by binding the enzyme to aminated EC via a succinyl residue; and EC-HMD-GA-CPA (IV), obtained by binding the enzyme via glutaraldehyde to a hexamethylene diamine derivative of EC. Full enzymic activity for all of the bound enzyme, such as that recorded for the immobilized CPA preparations EC-mAb.CPA and SPA.mAb.CPA, was not detected in any of the insoluble covalently bound enzyme preparations.     

具有谷氨酸脱羧酶的大肠杆菌固定化细胞

本文研究了用海藻酸钙包埋法制备含谷氨酸脱羧酶固定化细胞的方法以及研究了制备的条件和影响其制备的因素。该法具有包埋细胞活力回收高,方法简便等优点。比较研究了固定化细胞和自然细胞谷氨酸脱羧酶的一些生物化学性质。其中固定化细胞最适pH和pH稳定性增加,最适温度及热稳定性下降;表观米氏常数增大;二价金属离子Zn~(++)、Cu~(++)、Mg~(++)、Fe~(++),Sr~(++)程度不同的抑制酶活性,Ca~(++)激活固定化细胞酶活性,EDTA无抑制作用。对固定化细胞和自然细胞酶活力活化的研究中发现这两种细胞经蒸馏水保温处理后酶活性都上升,且自然细胞酶活的上升较固定化细胞大;而用底物溶液处理后,自然细胞无变化,固定化细胞酶活下降。     

Immobilization of cellulase and d-xylanase complexes from Aspergillus terreus F-413 on controlled porosity glasses

The major components of cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] and d-xylanase (see 1,4-β-d-xylan xylanohydrolase, EC 3.2.1.8) complexes have been immobilized on glass beads activated by 3-aminopropyltriethoxysilane or 3-glycidoxypropyltrimethoxysilane. The final preparations contained over 20 mg protein g^?1 glass beads. The activity retained was 71.6–98.1% for cellulase complexes and 81–100% for d-xylanase complexes. The immobilization of the enzymes spread their optimum pH range. Cellulose and d-xylan were quantitatively hydrolysed by the immobilized enzymes. The major reaction products were identified as a d-glucose and d-xylose respectively.     

Apparent cellulase activity of purified xylanase is due to contamination of assay substrate with xylan

Summary Purified xylanase A ofTrichoderma longibrachiatum was active on one of two carboxymethyl cellulose (CMC) preparations used as cellulase assay substrates. The pattern of enzyme activity, and analysis of the substrate by acid hydrolysis and thin-layer chromatography (TLC) suggested that the enzyme had acted on xylan present in the CMC.     

Bacteriolysis by immobilized enzymes.

Bacteriolytic enzymes produced by Achromobacter lunatus were immobilized in collagen membrane. Intact bacteria such as Pseudomonas solanacearum, Xanthomonas oryzae, Staphylococcus aureus, and Pseudomonas aeruginosa were lyzed with the bacteriolytic enzyme-collagen membrane. Relative activity of the bacteriolytic enzyme-collagen membrane against Pseu. solanacearum was about 2% of that of native bacteriolytic enzymes. No difference in the optimum pH was observed between immobilized enzymes and native enzymes. The bacteriolytic enzymes in the collagen membrane were stable against sodium chloride which was an inhibitor of the native bacteriolytic enzymes. Xanthomonas oryzae and Pseu. aeruginosa were continuously lyzed by a reactor containing the rolled bacteriolytic enzyme-collagen membrane.     

Glucose oxidase immobilized polyethylene-g-acrylic acid membrane for glucose oxidase sensor

A polyethylene-g-acrylic acid (PE-g-AA) graft copolymer was prepared via gamma-ray-irradiation-induced postirradiation procedures, and was used as support material for the immobilization of glucose oxidase. Soluble carbodiimides were used as the coupling agent. Reasonable yields were obtained with CMC but not with EDAC, EEDQ, or WRK. A number of factors were studied. (1) The use of water-soluble carbodiimides as condensing agent was attempted and the optimum condition for coupling glucose oxidase to PE-g-AA was established; (2) the effect of pH and temperature on the reactivity of native and immobilized glucose oxidase was studied. When exposed to temperatures in excess of 60 degrees C, the immobilized glucose oxidase was less sensitive to thermal inactivation than the native enzyme. The optimum pH value for the performance of the enzyme-immobilized membrane was 5. 6. For 200 tests, the response error of glucose sensor was less than 4% and its linear detected range was 0-1000 ppm. The obtained glucose oxidase-immobilized PE-g-AA membranes were kept in pH 5. 6 acetate buffer solution at 4 degrees C. The glucose oxidase activity of the membrane was determined at sevenday intervals. The membranes still have 92% glucose oxidase activity even after eight weeks of storage.     

Immobilization of the exo-maltohexaohydrolase by the irradiation method

Exomaltohexaohydrolase (E.C.3.2.1.98) was immobilized by radiocopolymerization of some synthetic monomers which were mixed in various combinations. Irradiation was carried out while the mixture of monomers and enzymes was frozen in petroleum ether-dry-ice bath. Recovery of the immobilized enzyme was 44-75%.The optimum pH of the enzyme slightly shifted to the acidic side. The pH stability was improved remarkably by immobilization. The enzyme was stable retaining more than 90% of its original activity in the range pH 4-11. The optimum reaction temperature of the enzyme increased about 2 degrees C. Heat stability was also improved by immobilization, and that the enzyme retained about 40% of its original activity after treatment at 75 degrees C for 15 min. The immobilized enzyme was stable to the repeated use of 20 cycles. The K(m) value of the enzyme for short-chain amylose was almost the same as that of native enzyme. When soluble starch was used as the substrate, the K(m), value of the enzyme was three times as large as that of native enzyme. Effects of various metal ions and inhibitors on the immobilized enzyme were also studied compared to the native enzyme.     

Investigation of the operational stabilities and kinetics of glucoamylase immobilized on alkylamine derivatives of titanium(IV)-activated porous inorganic supports

Glucoamylase (exo-1,4-α-d-glucosidase, EC 3.2.3.1) was coupled to several porous silica matrices by an improved metal-link/chelation process using alkylamine derivatives of titanium(IV)-activated supports. In order to select the titanium activation procedure which gave stable enzyme preparations, long-term stability tests were performed. The immobilized glucoamylase preparations, in which the carrier was activated to dryness with a 15% w/v TiCl₄ solution, displayed very stable behaviour, with half-lives of ～60 days. The optimum operating conditions were determined for these preparations. There are significant differences between the behaviour of the immobilized enzyme and the free enzyme. The apparent K_m increased on immobilization due to diffusional resistances. The pH optimum for the immobilized preparation showed a slight shift to acid pH relative to that of the soluble enzyme. Also, the optimum temperature descreased to 60°C after immobilization. In order to test Michaelis-Menten kinetics at high degrees of conversion, time-course analysis of soluble starch hydrolysis was performed. It was observed that simple Michaelis-Menten kinetics are not applicable to the free/immobilized glucoamylase-starch system at high degrees of conversion.     

Hydrolytic enzyme(s) production in Micrococcus roseus growing on different cellulosic substrates

Micrococcus roseus (G12) isolated from higher termite Odontotermes obesus gut exhibited cellulose digesting properties. A lignocellulosic substrate, rice husk induced endoglucanase, β-glucosidase, β-xylanase and β-xylosidase production. Besides rice husk, CMC also induced endoglucanase production. β-Glucosidase activity was quite pronounced when rice husk was supplemented with CMC or cellobiose. Both β-xylanase and β-xylosidase activities could be induced by xylan as well as xylobiose, whereas CMC induced partial activity. Endoglucanase and β-xylanase enzymes were secreted into the culture medium, whereas β-glucosidase and β-xylosidase activities were intracellular in nature. Enzyme production was subject to end product inhibition. The extracellular enzyme(s) possessed the potential to saccharify rice husk, xylan and CMC to reducing sugars.     

Immobilization of thermotolerant N-carbamyl-d-amino acid amidohydrolase

N-Carbamyl-d-amino acid amidohydrolase (DCase), in which amino acid residues were substituted by mutation, followed by the selection based on thermotolerance, showed improved thermostability, by 5° or 10°C, compared to the native DCase. These DCases were immobilized on a macroporous phenol formaldehyde resin, Duolite A-568, and the immobilized thermotolerant enzymes showed higher activity than the immobilized native DCase. From the results of repeated batch reactions, the half-lives of the activities of immobilized thermotolerant DCase, in which Leu was substituted for Pro 203, and immobilized native DCase were 104 and 58 times, respectively. It was revealed that the higher thermotolerance enabled the immobilized enzymes to be more stable in reactions. A reductant, dithiothreitol, also stabilized the enzymes in reactions. Compared with soluble DCase, immobilized DCase was somewhat stable, and its activity was optimum at a lower pH.     

Penicillin amidase from E. coli. A comparative study of the stability of penicillin amidase immobilized by various means]

The properties of immobilized penicillinamidases prepared by different methods were studied. Immobilization of penicillinamidase was achieved by using the covalend binding ion exchange sorption, incorporation into gel and other procedures. The effect of the carrier type, purification level of the native enzyme and other factors on stability of the immobilized preparations was studied. In 4 cases significant stabilization of the enzyme in the immobilized state was observed, while in 3 cases destabilization was registered.     

Properties of enzymes immobilized by the diazotized m-diaminobenzene method.

Some properties of a number of enzymes immobilized by the diazotized m-diaminobenzene (dDAB) method are described. The pH-activity profiles of beta-D-glucosidase, glucoamylase, peroxidase, uricase, and D-glucose oxidase were virtually unchanged on immobilization while those of catalase and dextranase were significantly altered. beta-D-Glucosidase, glucoamylase, and glucose oxidase were found to be more susceptible to denaturation on lyophilization when immobilized than in the native state; however, sorbitol had a marked protective effect in every case examined. Sorbitol was also found to exert a stabilizing effect when lyophilized immobilized preparations were stored. Immobilization marginally improved the stabilities of a number of enzymes to heating at 60 degrees at pH 8.0. The usefulness for continuous reaction of a column of glucoamylase attached to celite was established. The reuse of the solid supports was demonstrated.     

Preparation of immobilized alpha-amylase covalently attached to granular polyacrylonitrile

In this report, alpha-Amylase originating from Bacillus subtilis (liquefying type) was immobilized on partially imidoesterized polyacrylonitrile (PAN) by covalent bonding. For the preparation of immobilized alpha-amylase, which has a high activity and high stability to repeated use, the optimum conditions for the preparation reaction were investigated. The optimum conditions for the preparation reaction were quantified on the basis of the enzymatic activity, the preservation of the activity during repeated use in batch process and the protein content on the support. Further-more, enzymatic properties of immobilized alpha-amylase prepared at optimum conditions were compared with the native enzyme. The optimum temperature and reaction time for the imidoes-terification reaction were 30 degrees c and 6 h, respectively, whereas those of the amidinatin reaction were 30-40 degrees C and more than 3 h, respectively; the optimum pH range was 9-10. Immobilized alpha-amylase prepared at the optimum conditions was very stable against the repeated use and had more than 90% of relative to activity of the first use after the tenth procedure. The initial reaction rate of immobilized alpha-amylase was lower than native alpha-amylase, but same amount of reducing sugars were produced after the reaction passed for more than 90 min. The immobilized alpha-amylase was less stabel at the high temperature and the more basic media. However, after long incubation time, immobilized alpha-amylase was more stable than the native enzyme in exposure to heat and a storng base.     

锰过氧化物酶的耦合固定化及其性质研究

分别采用海藻酸钠、明胶和壳聚糖为载体,并以戊二醛为交联剂,通过包埋-交联和吸附-交联两种耦合固定化方法制备固定化锰过氧化物酶。探讨了酶的不同固定化条件和固定化酶的部分性能。与游离酶相比,制备的3种固定化酶最适反应pH分别由7·0降低到5·0、5·0和3·0,最适反应温度分别由35℃升高到75℃、55℃和75℃。3种固定化酶的耐热性都显著提高,其中用壳聚糖制成的固定化酶在pH2·2~11的宽范围内表现出很好的酸碱耐受性。30℃连续测定6~9次酶活力,重复使用的3种固定化酶显示出良好的稳定性。将固定化酶应用在偶氮染料的脱色中,用明胶制成的固定化酶在静置和摇床条件下,以及用海藻酸钠制成的固定化酶在摇床条件下,均表现出与游离酶相近的脱色能力,并且在重复进行的摇床实验中,脱色能力未降低,反应前后的酶活力均没有损失。