疏水吸附固定化天冬氨酸酶及其性质的研究

本文论述了一种N-烷基琼脂珠衍生物的合成方法,研究了pH,离子强度、载体上疏水基团含量等因素对载体吸附天冬氨酸酶的影响以及固定化天冬酸酶的性质。结果表明邻甲苯胺基琼脂珠在pH5.5,0.1mol/L磷酸缓冲液(含有0.25mol/LKCL)中,每克湿载体可吸附15—25mg酶蛋白,酶活力回收达90％以上。固定化酶的性质有所改变,其热稳定性和操作稳定性明显增强。 固定化天冬氨酸酸柱可以用于连续化生产L-天冬氮酸,在pH8.0,1.0mol/L及丁烯二酸铵(含0.02mol/L MgCl_2),30℃条件下,以空间流速SV=3.5操作2个月,固定化酶活力仍保持79.5％。     

漆酶在磁性壳聚糖微球上的固定及其酶学性质研究

以磁性壳聚糖微球为载体,戊二醛为交联剂,共价结合制备固定化漆酶。探讨了漆酶固定化的影响因素,并对固定化漆酶的性质进行了研究。确定漆酶固定化适宜条件为：50 mg磁性壳聚糖微球,加入10mL 0.8mg/mL 漆酶磷酸盐缓冲液（0.1mol/L,pH 7.0）,在4℃固定2h。固定化酶最适pH为3.0, 最适温度分别为10℃和55℃,均比游离酶降低5℃。在pH 3.0,温度37℃时,固定化酶对ABTS的表观米氏常数为171.1μmol/L。与游离酶相比,该固定化漆酶热稳定性明显提高,并具有良好的操作和存储稳定性。     

仿生法制备氧化硅载体固定化苏氨酸脱氨酶及其酶学性质

通过共沉淀法制备无机氧化硅载体,然后将其应用到苏氨酸脱氨酶的固定化研究中。用扫描电子显微镜对氧化硅载体进行表征,优化了固定化条件,当n(Si):n(N)为1∶1、偏硅酸浓度为0.03 mol/L、酶添加量为0.16mg/m L时,固定化的效率最高。接着对固定化酶和游离酶的酶学性质进行了考察,结果发现:固定化酶和游离酶的最适pH都是9.0,最适温度都是45℃,而相对于游离酶,固定化酶在pH 9.0~10.0和温度35~50℃范围内稳定性更好。固定化酶的米氏常数为7.48 mmol/L,重复使用15次后,酶活力保持80%以上。说明仿生氧化硅制备的固定化苏氨酸脱氨酶具有酶活回收率高、力学强度高和操作稳定性好等优势。     

N-乙酰神经氨酸醛缩酶的固定化及固定化酶性质研究

使用LX-1000HFA氨基树脂对N-乙酰神经氨酸醛缩酶(NAL)进行固定化,并对游离酶与固定化酶的酶学性质及稳定性进行了对比研究。结果显示,最佳固定化条件为载体投放量5.0 g,固定化时间12 h,缓冲液浓度1.0 mol/L,pH7.5,温度25℃。在此条件下制备的固定化NAL活力最高,比酶活可达200 U/g湿载体。与游离酶相比,最适反应温度提高了5℃,最适反应pH没有变化,温度和pH耐受性明显提升。同时固定化酶储存稳定性和操作稳定性也显著增强,在4℃条件下储存10 d后其酶活仅损失6%,重复使用10次后仍保持初始酶活的80%。因此,该固定化酶具有良好的温度稳定性、pH稳定性、储存稳定性和操作稳定性,为酶法工业化生产N-乙酰神经氨酸研究提供了理论依据。     

巨大芽孢杆菌青霉素G酰化酶在新型环氧载体ZH-HA上的固定化

巨大芽孢杆菌青霉素G酰化酶共价结合在新型环氧-氨基型载体ZH-HA 上,通过对酶浓度、固定化时间、pH以及缓冲液浓度等条件的考察,确定了最优固定化条件:50 mg比活力6000 U/g的巨大芽孢杆菌青霉素G酰化酶蛋白和1g ZH-HA悬浮于pH 9.01 mol/L磷酸缓冲液,室温搅拌6 h,制得固定化巨大芽孢杆菌青霉素G酰化酶,活力2126 U/g湿载体,活力回收率7.67%.比较研究了固定化酶与原酶性质,原酶最适温度45℃,最适pH为8.0.固定化酶则分别是50℃和9.0,分别比溶液酶偏移5℃、1.0个pH单位.经过40批连续水解青霉素G钾盐,固定化巨大芽孢杆菌青霉素酰化酶仍保持80%的活力,显示出良好的工作稳定性.     

M.natoriense TNJL143-2菌的D-氨基酰化酶的固定化研究

D-氨基酰化酶可用于D-氨基酸的生产,本研究利用来源于Microbacterium natoriense TNJL143-2的D-氨基酰化酶,分别通过琼脂糖包埋、介孔二氧化硅MCM-41和SBA-15吸附,制备了三种固定化酶,并对三种固定化酶的固定化条件、酶学性质、活性保持时间、重复使用次数、米氏常数等参数进行了研究。结果表明,MCM-41载体固定化酶的蛋白固定率为91.6%,SBA-15载体固定化酶的蛋白固定率为88.0%,琼脂糖包埋法蛋白固定率为79.5%。MCM-41、SBA-15以及琼脂糖三种载体固定化酶最适反应pH均为7.0,最适反应温度范围均为37℃。在固定化酶的活性保持时间以及重复利用活性方面,SBA-15固定化酶同样优于其他两种固定化酶。以D型苯丙氨酸(D-Phe)为底物时,琼脂糖包埋固定化酶的Km为28.8 mol/L,SBA-15固定化酶的Km为25.9 mol/L,MCM-41固定化酶的Km为25.0 mol/L。同时本文还探索了三种固定化酶的pH使用范围及酸碱稳定性、温度使用范围及热稳定性,结果显示,SBA-15作为固定化载体均表现出较广的适用范围及较高的稳定性。在不同条件的反应体系中,SBA-15固定化酶的蛋白损失率始终小于其他两种固定化酶。     

颗粒状固定化青霉素酰化酶的研究

将巨大芽孢杆菌 (Bacillusmegaterium)胞外青霉素酰化酶通过共价键结合到聚合物载体EupergitC颗粒环氧基团上 ,制成的颗粒状固定化青霉素酰化酶表现活力达 1 40 0 μ/g左右。固定化酶水解青霉素的最适 pH8 0 ,最适温度为 55℃。在pH6 0～ 8 5、温度低于 40℃时固定化酶活力稳定。在 pH8 0、温度 37℃时 ,固定化酶对青霉素的表现米氏常数Ka为 2×1 0 - 2 mol/L ;苯乙酸为竞争性抑制剂 ,抑制常数Kip为 2 8× 1 0 - 2 mol/L ;6 APA为非竞争性抑制剂 ,抑制常数Kia为 0 1 2 5mol/L。固定化酶水解青霉素 ,投料浓度为 8% ,在使用 2 0 0批后 ,保留活力 80 %左右 ,6 APA收率平均达 89 48%。     

固定化内切型肝素酶的研究

将提纯的一种内切型肝素酶固定于聚酯载体上 ,固定化效率达 78 8%。酶活力在pH为 7 5左右时表现最高 ,并且在此条件下固定化酶的稳定性最好。最适反应温度为 4 0℃。热稳定性试验表明 ,固定化酶的稳定性较差。固定化酶的使用半衰期比游离酶延长 4 4倍。固定化酶催化肝素底物反应的Km 值约为 95 4 μmol L而游离酶的Km 值约为 71 2 μmol L。固定化酶可以同时作用于肝素和硫酸乙酰肝素 ,而对硫酸软骨素没有催化能力。肝素经降解后 ,产生一定量的非硫酸化或低硫酸化的二糖和不同聚合度的寡糖混合物。     

活性炭吸附固定化粪产碱杆菌青霉素G酰化酶

目的：以活性炭为载体固定化粪产碱杆菌来源的青霉素G酰化酶,考察固定化酶的性质。方法：对影响酶固定化的因素优化筛选,确定有显著影响的因素：pH、离子强度、酶量、固定化时间进行L934的正交实验,获得最佳固定化条件,并对固定化酶的最适反应温度、pH及批次稳定性进行研究。结果：最佳固定化条件为：载体0.3g,酶量5mL,总反应体系为12mL,离子强度1mol/L,温度4℃,pH 7.0,固定化40h;最高固定化酶活性为135.9U/g湿载体。固定化酶性最适反应温度为55℃,最适pH为10,重复使用12次后没有活性损失。结论：活性炭吸附固定化青霉素G酰化酶的活性高,批次反应稳定,具有工业应用潜力。     

米曲霉F-81产中性蛋白酶的固定化条件及其特性

以海藻酸钠为载体,戊二醛为交联剂固定化米曲霉F-81产中性蛋白酶,研究了固定化条件及固定化酶的性质。结果表明,固定化的最佳条件为:固定化时间1 h、海澡酸钠浓度4%、戊二醛浓度9%、CaCl2浓度0.7 mol/L。在此条件下固定化的中性蛋白酶活力为游离酶活力的68%。固定化酶的最适作用温度为65℃,最适作用pH值为7.0。60℃下酶稳定性较好,80℃下处理60 min,粗酶中几乎检测不到酶活力;中性蛋白酶pH稳定范围为6.5-9.5。Km值为24.83 mg/mL,最大反应速率Vmax为0.043 12 mg/min。     

单宁酶的固定化及其在酯型儿茶素水解反应中的应用

采用自制的壳聚糖为载体对单宁酶（ＴＡ）固定化,ＴＡ与壳聚糖配比１：２．５,３０℃固定２ｈ,活力回收达２３．６％～３３．１％;偶联效率为８４．９％～８８．０％。固定化单宁酶（ＩＴＡ）的表观Ｋｍ值（以没食子酸丙酯为底物）为２２．２×１０－６ｍｏｌ／Ｌ,ＴＡ的Ｋｍ值（以没食子酸丙酯为底物）为１０×１０－６ｍｏｌ／Ｌ,ＴＡ和ＩＴＡ的最适反应温度分别为４０℃和５０℃;６０℃处理１５ｍｉｎ,残存活性分别为１３．６％和６０．３％。ＴＡ和ＩＴＡ的最适ｐＨ值分别为５．８和６．４;ＴＡ在ｐＨ４．８～７．８活力稳定,而ＩＴＡ活力稳定范围在ｐＨ４．８～６．８．ＩＴＡ作用于ＥＧＣＧ的半衰期为７８．７ｈ,ＥＧＣＧ水解率达９０．３％。对茶多酚提取物进行水解,其所含的酯型儿茶素ＥＧＣＧ和ＥＣＧ水解率分别为９６．４％和９６．８％,非酯型儿茶素ＥＧＣ和ＥＣ的含量显著增加。     

Continuous production of L-aspartic acid by immobilized aspartase

Various methods were tried for the immobilization of aspartase, and the preparation having the highest activity was obtained when partially purified aspartase from Escherichia coli was entrapped into polyacrylamide gel Iattice. Enzymatic properties of the immobilized aspartase were investigated and compared with those of the native aspartase. With regard to optimum pH, temperature, concentration of Mn⁺⁺, kinetic constants and heat stability, no marked difference was observed between the native and immobilized aspartases. By employing an enzyme column packed with the immobilized aspartase, conditions for continuous production of L -aspartic acid from ammonium fumarate were investigated. When a solution of 1M ammonium fumarate (pH 8.5, containing 1mM MnCl₂) was passed through the aspartase column at the flow rate of SV = 0.08 at 37°C, the highest rate of reaction was attained. From the column effluents, L-aspartic acid was obtained in a good yield.     

Immobilized Aspartase-Containing Microbial Cells: Preparation and Enzymatic Properties

The immobilization of asparatase-containing Escherichia coli was investigated by various methods, and the most active immobilized cells were obtained by entrapment in a polyacrylamide gel lattice. Other asparatase-containing bacteria were also entrapped by the same method, and the enzymatically active immobilized cells were obtained. The aspartase activity of the immobilized E. coli cells was increased nine- to tenfold by autolysis of the cells entrapped in the gel lattice. Enzymatic properties of the immobilized E. coli cells were investigated and compared with those of the intact cells. The optimal pH was 8.5 for the immobilized cells and 10.5 for the intact cells. The aspartase activities of immobilized and intact cells were not activated by Mn(2+), which can activate the immobilized and native aspartases. The heat stability of the immobilized cells was somewhat higher than that of the intact cells. Bivalent metal ions such as Mn(2+), Mg(2+), Ca(2+) protected against thermal inactivation of the aspartase activity of the immobilized and intact cells.     

黄曲霉毒素解毒酶的固定化及其性质的研究

黄曲霉毒素是农作物常见的受污染的霉菌毒素,毒性大,稳定性高,是潜在的肝癌致癌物,对人的危害较大。该毒素的解毒与去毒一直是受到关注的问题。黄曲霉毒素解毒酶对黄曲霉毒素有特殊的去毒和降解作用,但是该酶的稳定性离解决实际问题尚有一段距离。报道了对黄曲霉毒素解毒酶的固定化,并对固定化处理后酶的稳定性、性质、催化活性、解毒活性进行了测定。结果表明,通过固定化操作酶的解毒活性被保留下来,酶的酸碱稳定性、热稳定性、放置稳定性等均得到显著的提高。     

交联葡聚糖结合无花果蛋白酶的制备与性质

本文报道了将Sephadgx G-200与对β-硫酸酯乙砜基苯胺(SESA)首先醚化制备对氨基苯砜乙基交联葡聚糖(ABSE-Sephadex G-200),然后经重氮化固定无花果蛋白酶。固定化酶的活力回收达69％。BANA对该酶固定化过程中的活性变化有保护作用。天然酶与固定化酶都具有良好的耐热性,在69°～70℃,80min固定化酶较天然酶稳定。 用苯甲酰-DL-精氨酰-β-荼胺(BANA)为底物,在半胱氨酸存在下,测定了两种形式酶的动力学性质。在pH7.7的磷酸盐缓冲系统中,37℃,天然无花果蛋白酶的K_m=0.32mol/L;在间歇振摇下固定化酶的表观K′m=1.02mmol/L。最适pH无明显改变,均为pH7.7。     

Biodegradation of malachite green by Ochrobactrum sp.

This study presents the biodegradation of malachite green (MG), a triphenylmethane dye, using a novel microorganism isolated from textile effluent contaminated environment. The organism responsible for degradation was identified as Ochrobactrum sp JN214485 by 16S rRNA analysis. The effect of operating parameters such as temperature, pH, immobilized bead loading, and initial dye concentration on % degradation was studied, and their optimal values were found to be 30 °C, 6, 20 g/L and 100 mg/L, respectively. The analysis showed that the extracellular enzymes were responsible for the degradation. The biodegradation of MG was confirmed by UV–visible spectroscopic and FTIR analysis. The phytotoxicity test concluded that the degradation products were less toxic compared to MG. The kinetics of biodegradation was studied and the activation energy was found to be 10.65 kcal/mol.     

Kinetics of tributyrin hydrolysis by lipase

The kinetics for the tributyrin hydrolysis using lipase (Pseudomonas fluorscenes CCRC-17015) were investigated in the liquid–liquid and liquid–solid–liquid reaction systems in a batch reactor. The lipase was covalently immobilized onto the surface of porous polymethylacrylamide (PMAA) crosslinking with N,N-methylene biacrylamide with a spacer of ethylenediamine actived by glutaraldehyde. The conditions such as tributyrin concentration, temperature, agitation, and pH value, were evaluated to achieve the optimum reaction conditions for both free lipase and immobilized lipase. The kinetic parameters in the reaction system were also obtained for two reaction systems. The turnover numbers calculated for free lipase and immobilized lipase were 29 and 5.7 s⁻¹, respectively. The parameters of k and k_m obtained using Lineweaver-Burk plot method were 26.2 mol/(mg min) and 1.35 mol/dm³ for free lipase, 5.2 mol/(mg min) and 0.2 mol/dm³ for immobilized lipase, respectively. The experimental results revealed good thermal stability, with greater stability at higher pH value for immobilized lipase in the liquid–solid–liquid reaction.     

Immobilization of catalase into chemically crosslinked chitosan beads

Bovine liver catalase was immobilized into chitosan beads prepared in crosslinking solution. Various characteristics of immobilized catalase such as the pH–activity curve, the temperature–activity curve, thermal stability, operational stability, and storage stability were evaluated. Among them the pH optimum and temperature optimum of free and immobilized catalase were found to be pH 7.0 and 35 °C. The K_m value of immobilized catalase (77.5 mM) was higher than that of free enzyme (35 mM). Immobilization decreased in V_max value from 32,000 to 122 μmol (min mg protein)⁻¹. It was observed that operational, thermal and storage stabilities of the enzyme were increased with immobilization.     

Effect of inoculum composition and low KCl supplementation on the biological and rheological stability of an immobilized-cell system for mixed mesophilic lactic starter production.

Two strains of Lactococcus lactis subsp. lactis (L. lactis KB and KBP) and one of L. lactis subsp. lactis biovar. diacetylactis (L. diacetylactis MD) were immobilized separately in kappa-carrageenan-locust bean gum gel beads. Continuous fermentations were carried out in supplemented whey permeate in a 1-L pH-controlled stirred tank reactor inoculated with a 30% (v/v) bead inoculum and a bead ratio of 55:30:15 for KB, KBP, and MD, respectively. The process demonstrated a high productivity and microbial stability during the 7-week continuous culture. Compared with previous experiments carried out with an inoculum bead ratio of 33:33:33 for KB, KBP, and MD beads, respectively, the modification of the inoculum bead ratio had apparently little effect on free and immobilized, total and specific populations. A dominant behavior of L. diacetylactis MD over the other strains of the mixed culture was observed both with free-cell populations in the effluent and with immobilized-cell populations. Additional experiments were carried out with other strain combinations for continuous inoculation-prefermentation of milk. The data also confirmed the dominance of L. diacetylactis during long-term continuous immobilized-cell fermentations. This dominance may be tentatively explained by the local competition involved in the development of the bead cross-contamination and in citrate utilization by L. diacetylactis strains. The gel beads demonstrated a high rheological stability during the 7-week continuous fermentation even at low KCl supplementation of the broth medium (25 mM KCl).