枯草芽孢杆菌FM208849产果胶酶的固定化及酶学性质研究

为了提高游离果胶酶的稳定性,对罗布麻脱胶具有特异性的枯草芽孢杆菌(FM208849)进行产果胶酶发酵时,采用交联酶聚集体(CLEAs)技术制备固定化果胶酶,并对交联果胶酶聚集体的制备条件、酶学性质进行研究。结果表明,游离果胶酶经80%饱和硫酸铵沉淀后,在30℃,经4%的戊二醛溶液交联135 min,所形成的交联果胶酶聚集体的活回收率为61.5%,其最适反应温度45℃和最适pH10,在对交联果胶酶聚集体的热稳定性和有机溶剂稳定性分析中,均显示了比游离酶更高的稳定性。     

交联酶聚集体的制备及在漆酶固定化中的应用进展

漆酶是一种含铜的多酚氧化酶,其催化效率高,作用底物范围广,在工业中具有广阔应用前景。交联酶聚集体(CLEAs)是一种无需载体、无需酶纯化、制备简单、成本低的新型固定化酶方法,通常具有较高的稳定性,可实现酶的重复利用。对交联酶聚体制备过程中影响酶活性的相关因素以及其改进策略进行了分析,并对交联漆酶聚集体在污染物降解等方面的应用进行了总结,旨在为进一步的研究和应用奠定基础。     

戊二醛交联法制备壳聚糖固定化酶的改进研究

壳聚糖是由是虾、蟹壳蛋白中提取的一种氨基多糖（２氨基１,４-β葡聚糖）,呈网状结构,由于其来源丰富,制备简单,化学性质稳定,耐热和具有良好的机械性能,是固定化酶的良好载体,在医药及工业上有着广阔的应用前景^[1].为此探索酶固定化方法,提高酶利用率,活性回收率,提高稳定性和使用周期是固定化酶研究的重要课题。戊二醛交联法是制备固定化酶常用的方法,为防止戊二醛直接和载体分子中氨基间可能会发生的交联反应,本文采用醛基保护改进戊二醛交联法制备了壳聚糖固定化酶,并对其酶利用率,活性回收率进行了观察和比较。     

过氧化氢酶对固定化葡萄糖氧化酶稳定性的影响

本文通过重氮盐共价键合法把葡萄糖氧化酶接到交联琼脂糖上制备固定化酶。为了提高固定化酶的使用稳定性,把过氧化氢酶和葡萄糖氧化酶同时接到载体上,并研究了这两种酶在不同比例时对固定化葡萄糖氧化酶活力和稳定性的影响,随着加入过氧化氢酶量的增加,固定化葡萄糖氧化酶稳定性显著增加。所制得的固定化葡萄精氧化酶-过氧化氢酶在25℃下连续使用36h,活力几乎不变,失活半衰期可达1155h。     

固定化黑曲霉β-葡萄糖苷酶制备染料木素活性苷元的研究

比较了以海藻酸钠为载体,用胶囊法、包埋-交联法、交联-包埋法三种不同方法固定化黑曲霉β-葡萄糖苷酶的效果,并研究了最佳固定化方法的固定化条件和固定化酶的部分性质。结果表明,交联-包埋法即β-葡萄糖苷酶与0.20%戊二醛交联后再用2.0%海藻酸钠包埋的固定化方法中酶结合效率和酶活力回收率最高。海藻酸钠浓度和戊二醛浓度对酶结合效率影响较大,戊二醛浓度和包埋颗粒直径大小对酶活力回收率影响显著。与游离酶相比,制备的固定化酶最适温度、最适pH值和Km值分别由50℃、4.5和2.57μg/mL下降到40℃、4.0和2.02μg/mL。固定化酶具有更强的耐酸性和稳定性。该固定化酶用于大豆异黄酮活性苷元染料木素的合成,重复使用6次后,固定化酶的活力仍保持84.94%,染料木苷转化率为56.04%。     

桦褶孔菌漆酶固定化及其对染料的降解

采用壳聚糖交联法和海藻酸钠-壳聚糖包埋交联法固定化桦褶孔菌产生的漆酶,探讨最佳固定化条件,固定化漆酶的温度,pH稳定性及操作稳定性,并以两种固定化酶分别对4种染料进行了降解.结果表明:(1)壳聚糖交联法固定化漆酶的最佳条件为:壳聚糖2.5%,戊二醛7%,交联时间2h,固定化时间5h,给酶量1g壳聚糖小球:1mL酶液(1U/mL),固定化效率56%;(2)海藻酸钠-壳聚糖包埋交联法固定化漆酶的最佳条件为:海藻酸钠浓度4%,壳聚糖浓度0.7%,氯化钙浓度5%,戊二醛浓度0.6%,给酶量4mL 4%海藻酸钠:1mL酶液(1U/mL),固定化效率高达86%;(3)固定化的漆酶相比游离漆酶有更好的温度和pH稳定性;(4)比较两种固定化漆酶,海藻酸钠-壳聚糖包埋交联法固定化酶的温度及酸度稳定性要优于壳聚糖固定化酶,但可重复操作性要弱于后者,两者重复使用8次后的剩余酶活比率分别为71%及64%;(5)两种固定化酶对所选的4种不同结构的合成染料均有较好的降解效果,其中壳聚糖固定化酶对茜素红的降解效果及重复使用性极佳,重复降解40mg/L的茜素红10次,降解率仍保持在100%.     

酶的定向固定化方法及其对酶生物活性的影响

固定化酶可以提高酶的稳定性,但通常酶通过酶分子上的多个赖氨酸残基随意固定在载体上,这样会使酶的活性显著下降,采用定向固定化酶不仅可以提高酶的稳定性,而且可以保存它的活性。综述了定向固定化酶的几种方法,比较了定向固定化和随意固定化对酶活性的影响。另外,还叙述了酶的活性位点结构变化的自旋共振波谱(EPR)检测。     

“构象记忆”的辣根过氧化物酶的微水相共价固定化

本研究利用酶在微水溶剂中的"构象记忆"特性,以壳聚糖微球为载体,以辣根过氧化物酶(Horseradish peroxidase,HRP)为研究对象,将HRP于活性构象下冻干"固定"后,在二氧六环:水=99:1(V/V)微水介质中与载体进行共价交联,同时与传统水介质中共价交联固定化的HRP进行比较。结果发现,两种介质中固定化HRP的最适温度都提高到60°C,最适pH均为6.5,而微水相中固定的酶活力损失较低,酶活比传统水相中固定的酶高6倍以上;70°C保温30min后,微水相中固定的酶保留75.42%的活力,而水相中固定的HRP仅存15.4%的活力;微水相中固定的HRP具有更好的操作稳定性和热稳定性,60°C下连续操作5次之后,微水相固定的HRP保留77.69%的酶活,而水相固定的HRP仅存16.67%的酶活;微水相中固定的HRP在苯酚的去除中表现得更具优势;微水相中共价交联制备的CS-HRP-SWCNTs/Au酶修饰电极对H2O2的响应信号比水相中共价固定的酶电极强2.5倍,灵敏度更高。本研究表明利用酶的"构象记忆"在微水介质中进行共价交联是固定化酶的一种可行方法,所制备的固定化酶具有更优良的性质。     

固定化黑曲霉β-葡萄糖苷酶制备染料木素活性苷元的研究

比较了以海藻酸钠为载体,用胶囊法、包埋-交联法、交联-包埋法三种不同方法固定化黑曲霉β-葡萄糖苷酶的效果,并研究了最佳固定化方法的固定化条件和固定化酶的部分性质。结果表明,交联-包埋法即β-葡萄糖苷酶与0.20%戊二醛交联后再用2.0%海藻酸钠包埋的固定化方法中酶结合效率和酶活力回收率最高。海藻酸钠浓度和戊二醛浓度对酶结合效率影响较大,戊二醛浓度和包埋颗粒直径大小对酶活力回收率影响显著。与游离酶相比,制备的固定化酶最适温度、最适pH值和K_m值分别由50℃、4.5和2.57 μg/mL下降到40℃、4.0和2.02 μg/mL。固定化酶具有更强的耐酸性和稳定性。该固定化酶用于大豆异黄酮活性苷元染料木素的合成,重复使用6次后,固定化酶的活力仍保持84.94%,染料木苷转化率为56.04%。     

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pH 2.2～11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。     

Enzyme activity down to -100 degrees C

The activities of two enzymes, beef liver catalase (EC 1.11.1.6) and calf intestine alkaline phosphatase (EC 3.1.3.1), have been measured down to -97 degrees C and -100 degrees C, respectively. Enzyme activity has not previously been measured at such low temperatures. For catalase, the cryosolvents used were methanol:ethylene glycol:water (70:10:20) and DMSO:ethylene glycol:water (60:20:20). For alkaline phosphatase, methanol:ethylene glycol:water (70:10:20) was used. All of the Arrhenius plots were linear over the whole of the temperature range examined. Since the lowest temperatures at which activity was measured are well below the dynamic transition observed for proteins, the results indicate that the motions which cease below the dynamic transition are not essential for enzyme activity. In all cases the use of cryosolvent led to substantial increases in Arrhenius activation energies, and this imposed practical limitations on the measurement of enzyme activity below -100 degrees C. At even lower temperatures, enzyme activity may be limited by the effect of solvent fluidity on substrate/product diffusion, but overall there is no evidence that any intrinsic enzyme property imposes a lower temperature limit for enzyme activity.     

Enzyme catalysed reactions in water - Organic solvent two-phase systems

Enzyme-catalysed transformations carried out in two-phase systems consisting of water and a water-immiscible organic solvent are discussed. The systems appear advantageous when substrates poorly soluble in water, such as steroids, are used. The methodology also makes possible the use of hydrolytic enzymes for the synthesis of ester bonds. Several applications of such two-phase systems are illustrated. The criteria that must be taken into consideration for selecting the most suitable organic solvents and the operational conditions are discussed.     

A New Proteolytic Enzyme from Achromobacter lyticus M497-1

Potent antioxidative hydroxyflavanones were produced with Aspergillus saitoi from hesperidin or naringin, which are flavanone glycosides in citrus fruit with weak antioxidative activity. The hydroxyflavanone produced from hesperidin was identified as 8-hydroxyhesperetin (8-HHE), a novel substance, and those from naringin were identified as carthamidin (6-hydroxynaringenin) and isocarthamidin (8-hydroxynaringenin) by FAB-MS, ¹H-NMR and ¹³C-NMR analyses. The antioxidative activity of these hydroxyflavanones was examined by using the free radical-scavenging system of 1,1-diphenyl-2-picrylhydrazyl (DPPH) and the methyl linoleate oxidation system. The hydroxyflavanones (8-HHE, carthamidin, and isocarthamidin) exhibited stronger activity than the flavanone glycosides (hesperidin or naringin) and their aglycones (hesperetin or naringenin). The activity of 8-HHE and isocarthamidin was comparable to that of α-tocopherol, and that of carthamidin was weaker than that of isocarthamidin. The hydroxyflavanones, which were hydroxylated on A ring of flavanone by Aspergillus saitoi, were obtained as potent antioxidants.     

酶法提取玉米胚中总黄酮的研究

尝试使用α-淀粉酶进行糖苷转移提取玉米中总黄酮,同时对α-淀粉酶的固定化进行研究。对α-淀粉酶固定化的研究表明:以壳聚糖为载体,用体积分数4%戊二醛进行交联,加酶量为3 g.L-1条件下可以获得最佳的固定化效果;与游离酶相比,其最适作用温度范围、pH值范围均比游离酶范围宽;固定化酶的热稳定性优于游离酶,且具有良好的操作稳定性。本试验使用游离酶法、固定化酶法提取玉米中总黄酮,得率分别为2.82%、2.46%。     

酶模型

结合各相关专著、文献中对酶模型的介绍,简要回顾了酶模型的发展背景,较系统综述了其概念、理论基础、主要类型及该领域的研究进展。     

Enzyme deactivation

Enzyme deactivation kinetics is often first-order. Different examples of first-order deactivation kinetics exhibited by different enzymes under a wide variety of conditions are presented. Examples of both soluble and immobilized enzymes are presented. The influence of different parameters, chemical modification of specific residues, inhibitors, inactivators, protecting agents, induced conformational changes by external agents, enzyme concentration, and different substrates on the first-order inactivation kinetics of different enzymes is analyzed. The different examples presented from a variety of different areas provides a judicious framework and collection demonstrating the wide applicability of first-order deactivation kinetics. Examples of reversible first-order deactivation kinetics and deactivation-disguise kinetics are also presented.Different mechanisms are also presented to model complex enzyme deactivations. The non-series type mechanisms are emphasized and these involve the substrate and chemical modifiers. Substrate-dependent deactivation rate expressions that are of "separable" and "non-separable" type are presented. Rate expressions involving time-dependent rate constants along with their corresponding mechanisms are presented. Examples of enzymes that exhibit a deactivation-free grace period are also given. An interesting case of enzyme inactivation is the loss of activity in the presence of an auto-decaying reagent. The method is presented by which the intrinsic inactivation rate constants may be obtained. Examples of pH-dependent enzyme inactivation are presented that may be modelled by a five-step (or a simplified two-step) mechanism, and also by a single-step mechanism involving residual activity for the final state. Appropriate examples of enzyme inactivation are presented in each case to highlight the different mechanisms involved.