加速器质谱法研究尼古丁与小鼠血液蛋白的加合作用

采用加速器质谱法（AMS）研究了小鼠血液中的血红蛋白（Hb),白蛋白（SA）和尼古丁和加合作用，在尼古丁剂量从相应于人吸烟的环境剂量水平0．1μg/kg体重到100μg/kg体重范围内，测量了尼古丁－血红蛋白加合物和尼古丁－白蛋白加合物的剂量效应曲线，两种蛋白的尼古丁加合物水平都随着尼古丁剂量的升高耐线性增加，在实验剂量范围内，两种蛋白质加合物的水平与小鼠肝DNA加合物水平也呈现良好的线性关系，这说两种蛋白质加合可以替代DNA加合物作为尼古丁的生物标记物，在本工作中，蛋白质加合物的测量灵敏度为0．03pmol/g蛋白（即3．2个加合物／10^12氨基酸残基），达到了文献报道的测量蛋白质生物标记物最高的灵敏度。     

基于吐温-姜黄素复合物的荧光探针检测脂肪酶活性

本实验以姜黄素作为信号探针,吐温作为脂肪酶的底物和包裹姜黄素的载体,建立了一种检测脂肪酶活性的荧光法.实验发现,采用0.3 mmol/L吐温40,25 μmol/L姜黄素,并且脂肪酶水解吐温40的时间为35 min时,姜黄素的荧光强度变化值与脂肪酶浓度在0.002 ～0.05 mg/mL和0.05～0.25 mg/mL范围内呈现线性关系,检出限为0.6 mg/L (S/N=3).此探针在高通量检测脂肪酶活性以及与脂肪酶相关疾病检测领域中有较好的应用前景.     

构建基于姜黄素-Hg~(2+)复合物的荧光传感器检测脂肪酶活性

以吐温40-姜黄素复合物胶束为荧光信号探针,Hg~(2+)为猝灭剂,巯基乙酸甲酯为脂肪酶的底物,构建了检测脂肪酶活性的生物传感器。利用Hg~(2+)与姜黄素β-二酮结构结合,猝灭吐温40-姜黄素复合物胶束荧光;而脂肪酶的加入催化了巯基乙酸甲酯水解生成巯基乙酸,巯基乙酸夺取姜黄素-Hg~(2+)复合物上的Hg~(2+),吐温40-姜黄素复合物胶束的荧光恢复,荧光恢复强度与脂肪酶的活性相关。利用此荧光传感策略定量检测脂肪酶活性,在最佳实验条件下,荧光强度变化值与脂肪酶活性在2~80 U/mL范围内呈线性关系,检出限为0.01 U/mL。采用此方法对另外4种商业脂肪酶的活性进行了检测,实验结果与恒电位滴定法测定结果一致。本方法检测成本低,操作简单,灵敏度高,具有良好的实用性,可用于脂肪酶活性的高通量检测。     

基于氢键诱导的纳米金比色传感器实时检测脂肪酶活性

以巯基乙酸甲酯(MT)修饰的纳米金(AuNPs)为探针,构建了比色生物传感器检测脂肪酶活性.在pH 6.5弱酸性条件下,脂肪酶水解MT-AuNPs上的酯键生成带负电荷的羧酸根;在pH 3.0的酸性条件下,探针间会产生强烈的氢键作用使AuNPs聚集,基于此可以检测脂肪酶活性.考察了温度、pH等因素对传感器响应信号的影响.MT-AuNPs溶液在650和520 nm处的吸光度比值A650/A520与脂肪酶活性大小在3.0×10-4 ～4.5 ×10-2 U/mL范围内呈现良好的线性关系,检出限为2.25×10-4 U/mL(S/N=3).测定了5种商品化脂肪酶的活性,实验结果与恒电位滴定法测定结果一致,证明本方法具有良好的实用性.     

聚苯胺／聚乙烯醇载体尼古丁膜电极的研究

聚苯胺／聚乙烯醇复合物与四苯硼钠－尼古丁混合，制成尼古丁膜电极，在ｐＨ＝２～７电极时１０＾－２～１０＾－５ｍｏｌ／Ｌ的尼古丁有良好的线性响应，检测下限可达４．０×１０＾－６ｍｏｌ／Ｌ。用于烟草样品中尼古丁含量的测定，平均回收率为９８．４％，相对标准偏差为０．９３％，与紫外分光光度法对比，结果令人满意。     

混合溶剂系统中固定化脂肪酶对酮基布洛芬的催化酯化反应

以硅藻土吸附的脂肪酶为催化剂，对外消旋酮基布洛芬－［２－（３－苯甲酰苯基）丙酸］进行对映选择性酯化反应；考察了不同的脂肪酶制剂，固定化时所加缓冲剂的体积与ｐＨ值，酰基受体（醇）的种类以及混合溶剂系统的组成等因素对酶活性的影响。结果表明，在所考察的７种脂肪酶中，以Ｌｉｐａｓｅ ＯＦ的酯化活性最高；用硅藻土吸附固定化酶时，缓冲溶液的最适ｐＨ为７．０左右，每克酶粉加１．０ｍＬ缓冲溶液为最佳；固定化酶催化     

脂肪酶直接与硅胶混合催化无溶剂酯化反应的研究

用硅胶作为载体，以癸酸与己醇的酯化反应作为模型，将脂肪酶和底物直接与硅胶混合，用于无溶剂体系催化酯化反应．结果表明体系中水的含量、底物用量比以及反应时间均对酯化反应有较大影响．在该体系中，脂肪酶催化酯合成反应的速度显著增加，反应2h后．转化率可以达到90％以上．而且沉积在硅胶上的脂肪酶可以反复使用多次．     

结合分子模拟探讨PC脂肪酶催化PBS基共聚物降解的主链异构效应

采用固定化洋葱假单胞菌脂肪酶(Pseudomonas cepacia lipase,PC脂肪酶)为催化剂,在有机溶剂体系中研究了环己烷二甲醇和环己烷二甲酸对聚丁二酸丁二醇酯(PBS)的改性共聚物,即聚(丁二酸丁二醇-co-丁二酸环己烷二甲醇酯)(PBS-co-CHDMS)和聚(丁二酸丁二醇-co-环己烷二甲酸丁二醇酯)(PBS-co-BCHDA)的降解规律及其差异性.通过共聚物降解率随时间的变化、降解产物的MALDI-TOF-MS分析研究了共聚物降解规律,并以分子模拟分别研究了降解差异性和PC脂肪酶与底物的结合机制.研究结果表明,PC脂肪酶均可催化PBS基共聚物降解;在降解60 h后,相比较于PBS-co-BCHDA,PBS-co-CHDMS降解率均更大;其中PBS-co-10%CHDMS降解率最大,为85%.共聚物降解不仅生成了线型小分子,还产生了部分环状低聚物;此外,PBS-co-CHDMS降解产生的低聚物种类比PBS-co-BCHDA的要多.分子对接模拟结果表明,在氯仿中,PC脂肪酶与底物结合自由能的大小顺序为CMSCMBSCMBCABBSB,即含有丁二酸环己烷二甲醇酯(CHDMS)单元的底物与PC脂肪酶活性位点的对接更为稳定.     

来源于类芽孢杆菌属新型耐有机溶剂脂肪酶的克隆、表达与性质研究（英文）

脂肪酶(EC 3.1.1.3)全称为三酰基甘油水解酶,是一类能够将长链脂肪酸甘油酯水解成脂肪酸和二甘酯、单甘酯或甘油的酯键水解酶.它除了能够水解脂肪外,还具有催化酯化反应、酯交换反应、酸解反应、醇解反应以及氨解等反应的性质.在脂肪酶催化的反应中,通常用有机溶剂代替水.有机溶剂可以转移合成反应的平衡方向,通过溶剂工程修饰酶的选择性能够提高底物的溶解度、有机相产物的回收率、酶的热稳定性.但有机溶剂对酶活性和稳定性有不同程度的影响.因此,寻找在有机溶剂中表现出高活性和稳定性的脂肪酶是一个亟待解决的重要课题.由于微生物种类多、作用底物专一性强,且微生物来源的脂肪酶一般分泌到胞外,因此微生物脂肪酶是工业用脂肪酶的重要来源.目前,微生物脂肪酶的研究主要集中于根霉属(Rhizopus)、曲霉属(Aspergillus)、青霉属(Penicillium)、毛霉属(Mucor)、地霉属(Geotrichum)、假丝酵母属(Candida)、假单胞菌属(Pseudomonas)、伯克霍尔德菌属(Burkholderia)等具有工业应用价值的菌株.很少有类芽孢杆菌属所产脂肪酶进行相关酶学性质的研究.我们以Paenibacillus pasadenensis CS0611为出发菌株,在全基因序列草图中得到了一个新型脂肪酶基因lp2252.以Paenibacillus pasadenensis CS0611基因组为模板,设计特异性引物对目标序列进行扩增,并成功将其插入到表达载体p ET-28a中得到含有目的基因的重组质粒.在E.coli BL21(DE3)中,脂肪酶lp2252经0.1mmol/L的IPTG诱导后在20°C实现了高水平表达.重组脂肪酶的活性约为野生型的1631倍.用镍离子亲和层析柱快速、高效地纯化了两端带有组氨酸标签的重组脂肪酶,回收率为63.5%,纯化因子为10.78.纯化后的脂肪酶最适温度为50°C,在20-40°C范围内具有良好的稳定性.最适pH值为7,属于中性脂肪酶,同时在pH 3.0-8.0间具有较高稳定性.在金属离子如钙、镁离子和一些非离子表面活性剂的作用下,其活性有所提高.此外,纯化后的脂肪酶可被一系列水溶性有机溶剂激活,例如一些短链醇.而对某些水不溶性有机溶剂,其也具有高度的耐受性.综上所述,本文所涉新型脂肪酶在非水相催化领域具有广泛的应用和前景.     

同时测定室内吸烟环境空气中尼古丁和3-乙烯基吡啶的方法

以XAD-4树脂为吸附剂，含三乙胺0．0l％的乙酸乙酯为溶剂，GC／MS为检测手段，以及内标校正曲线定量，建立一套可以同时测定吸烟环境室内空气中尼古丁和3-乙烯基吡啶标志物含量的分析方法。尼古丁的检出限和平均脱附率分别为0．075μg/样品和91．80％；3-乙烯基吡啶分别为0．089μg/样品和95．90％。通过实际样品的测定，讨论了该方法的应用效果。     

Effects of Organic Solvents on Immobilized Lipase in Pectin Microspheres

Lipase from Brevibacillus agri 52 was found stable up to 90% diethylenglycol (DEG), glycerol (GLY), and 1,2 propanediol (1,2 PRO) at 37 degrees C for 1 h and the stability was reduced only approximately 20% after 12 h incubation, but in 40% dimethylsulfoxide (DMSO), lipase activity was stable only for 1 h. Inhibition of the biocatalysts with dimethylformamide (DMF) was detected at 20% solvent concentration. In water immiscible systems, the stability of lipase in n-hexane, n-tetradecane and n-heptane resembles the water activity, but in the presence of isobutanol, 1-hexanol, and butylbutirate, the stability was significantly reduced. Lipase 52 precipitates in the presence of 50% acetone or ethanol/water mixtures, but enzymatic activity was partially recovered by adding 20% GLY, DEG, 1,2 PRO, or DMSO to the reaction mixture. Furthermore, by increasing DEG in 70% DMF/DEG mixtures, the lipase activity was protected. Encapsulation of lipase in pectin gels cross-linked with calcium ions brings three to four times more enzymatic activity in 70% water miscible organic solvents compared to aqueous systems.     

STUDY ON IMMOBILIZED PORCINE PANCREATIC LIPASE CATALYZING TRANSESTERIFICATION BETWEEN METHYL－BUTYRATE AND 1－BUTANOL IN NONAQUEOUS SYSTEMS

ＳＴＵＤＹＯＮＩＭＭＯＢＩＬＩＺＥＤＰＯＲＣＩＮＥＰＡＮＣＲＥＡＴＩＣＬＩＰＡＳＥＣＡＴＡＬＹＺＩＮＧＴＲＡＮＳＥＳＴＥＲＩＦＩＣＡＴＩＯＮＢＥＴＷＥＥＮＭＥＴＨＹＬ－ＢＵＴＹＲＡＴＥＡＮＤ１－ＢＵＴＡＮＯＬＩＮＮＯＮＡＱＵＥＯＵＳＳＹＳＴＥＭＳＸｉ...     

STUDY ON IMMOBILIZED PORCINE PANCREATIC LIPASE CATALYZING TRANSESTERIFICATION BETWEEN METHYL—BUTYRATE AND 1—BUTANOL IN NONAQUEOUS SYSTEMS

Transesterification between methyl-butyrate and 1-butanol in nonaqueous systems was catalyzed by porcine pancreatic lipase which was immobilized on cross-linked polystyrene.Organic solvents,substrate concentration,contents of water and other parameters which affect the immobilized enzyme activity were studied.Lipase immobilized on hydrophobic crosslinked polystyrene can reduce its diffusion limit in the reaction.It was found that the activity of immobilized lipase in organic systems was two times as high as that of free lipase.     

Effect of Additives on Freeze-Drying and Storage of Yarrowia lipolytica Lipase

The extracellular lipase of Yarrowia lipolytica presents numerous potentialities for biotechnological applications. This work describes the development and storage of powders obtained from supernatants containing Y. lipolytica lipase by freeze-drying as downstream process that is important in obtaining a stable lipase powder with high enzymatic activity. Lipase was produced by Y. lipolytica U6 mutant strain in 20-L bioreactor. Non-concentrated cell-free culture supernatant samples were supplemented with different concentrations (0.5?C1?%) of maltodextrin and glycerol as additives to freeze-drying. Effects of additives, temperature, pH, and storage time on lipase powders were determined. After addition of additives, freeze-drying yield increased 3.5-fold compared to supernatant without additive. Maltodextrin with 0.5?% concentration gave the best protection of lipase during dehydration treatment and its freeze-drying yield (77?%) is better than other formulations. Lipase powders were stored at 4 and 25?°C for 46?weeks without loss of lipase activity. A common impediment to the production of commercial enzyme is their low-stability aqueous solutions. The present study shows that freeze-dried lipase powders of Y. lipolytica have good stability for storage and various applications.     

Nonionic surfactants: a key to enhance the enzyme activity at cationic reverse micellar interface

The primary objective of the present study is to understand how the different nonionic surfactants modify the anisotropic interface of cationic water-in-oil (W/O) microemulsions and thus influences the catalytic efficiency of surface-active enzymes. Activity of Chromobacterium viscosum lipase (CV-lipase) was estimated in several mixed reverse micelles prepared from CTAB and four different nonionic surfactants, Brij-30, Brij-92, Tween-20, and Tween-80/water/isooctane/n-hexanol at different z ([cosurfactant]/[surfactants]) values, pH 6 (20 mM phosphate), 25 degrees C across a varying range of W0 ([water]/[surfactants]) using p-nitrophenyl-n-octanoate as the substrate. Lipase activity in mixed reverse micelles improved maximum up to approximately 200% with increasing content of non-ionic surfactants compared to that in CTAB probably due to the reduced positive charge density as well as plummeted n-hexanol (competitive inhibitor of lipase) content at the interfacial region of cationic W/O microemulsions. The highest activity of lipase was observed in CTAB (10 mM) + Brij-30 (40 mM)/isooctane/n-hexanol)/water system, k2 = 913 +/- 5 cm3 g-1 s-1. Interestingly, this observed activity is even higher than that obtained in sodium bis (2-ethyl-1-hexyl) sulfosuccinate (AOT)/n-heptane reverse micelles, the most popular W/O microemulsion in micellar enzymology. To ascertain the influence of non-ionic surfactants in improving the activity of surface-active enzymes is not limited to lipase only, we have also investigated the catalytic activity of Horseradish peroxidase (HRP) in different mixed W/O microemulsions. Here also following the similar trend as observed for lipase, HRP activity enhanced up to 2.5 fold with increasing concentration of nonionic surfactants. Finally, the enzyme activity was correlated with the change in the microenvironment of mixed reverse micelles by steady-state fluorescence study using 8-anilino-1-napthalenesulphonic acid (ANS) as probe.     

Lipase Immobilized on the Hydrophobic Polytetrafluoroethene Membrane with Nonwoven Fabric and Its Application in Intensifying Synthesis of Butyl Oleate

The synthesis of butyl oleate was studied in this paper with immobilized lipase. Five types of membrane were used as support to immobilize Rhizopus arrhizus lipase by following a procedure combining filtration and protein cross-linking. Results showed that hydrophobic polytetrafluoroethene membrane with nonwoven fabric (HO-PTFE-NF) was the favorite choice in terms of higher protein loading, activity, and specific activity of immobilized lipase. The factors including solvent polarity, lipase dosage, concentration, and molar ratio of substrate and temperature were found to have significant influence on conversion. Results showed that hexane (logP = 3.53) was a favorable solvent for the biosynthesis of butyl oleate in our studies. The optimal conditions were experimentally determined of 50 U immobilized lipase, molar ratio of oleic acid to butanol of 1.0, substrate concentration of 0.12 mol/L, temperature of 37 °C, and reaction time of 2 h. The conversion was beyond 91% and decreased slightly after 18 cycles. Lipase immobilization can improve the conversion and the repeated use of immobilized lipase relative to free lipase.     

Poly(ethylene glycol)-lipase complexes catalytically active in fluorous solvents

Lipase-catalyzed alcoholysis between vinyl cinnamate and benzyl alcohol in fluorous solvents was investigated. This is the first report of a lipase-catalyzed reaction in a fluorous solvent. Forming the poly(ethylene glycol)(PEG)-lipase PL complex enhanced lipase activity over 16-fold over that of native lipase powder. The PEG-lipase PL complex exhibited markedly higher alcoholysis activities in fluorous solvents than in conventional organic solvents such as isooctane and n-hexane. The optimum reaction temperature for FC-77 (perfluorooctane) was 55 [degree]C and the optimum pH for the preparation of the PEG-lipase complex was 9.0; similar to the conditions for lipase PL-catalyzed reaction in aqueous solution. The alcoholysis reaction in fluorous solvent requires the addition of a FC77-miscible organic solvent (isooctane) in order to dissolve non-fluorinated substrates. Lipase activity in the fluorous solvent was significantly influenced by the volume ratio of isooctane in the reaction medium. Vinyl cinnamate inhibition of the lipase-catalyzed reaction occurred at a much lower concentration in the fluorous solvent than in isooctane. These results can be explained by the localization of substrates around lipase molecules, induced by adsorption of the substrates to the PEG layer of the PEG-lipase complex.     

大环碳酸酯的Novozym-435酶促开环聚合

研究了14元环的碳酸丁二酯二聚体在固定化脂肪酶Novozym-435催化下的开环聚合反应制备聚碳酸丁二酯.聚合在常压,75℃的甲苯溶液中进行,反应条件温和.详细探讨了反应条件诸如单体浓度,酶浓度对于聚合的影响.结果显示Novozym-435具有与异辛酸亚锡可比拟的高催化活性,同时可以回收重复使用.聚合动力学研究表明碳酸丁二酯的酶促甲苯溶液开环聚合和环状内酯的酶促甲苯溶液聚合有所不同,没有表现出活性聚合的特征.     

Lipase biosensor for tributyrin and pesticide detection

Potentiometric biosensors based on Candida rugosa lipase was described for the detection of organophosphorus pesticide; methyl-parathion and tributyrin. Lipase was immobilized on the glass electrode by means of a gelatin membrane, which is then cross-linked with glutaraldehyde. The principle of the biosensor is based on the measurement of pH variation which was recorded in millivolts due to the enzymatic hydrolysis of tributyrin to butyric acid. For the inhibitor detection, biosensor responses were measured after pesticide treatment, which caused a drop in enzyme activity because of the irreversible inhibition. Reactivation conditions of the reused enzyme electrodes were also investigated by pyridine-2-aldoxime methiodide (2-PAM). The limit of detection for tributyrin was estimated as 93?µM for lipase sensor within the linear range of 65–455?µM.     

Development of a lipase-based optical assay for detection of DNA

A lipase-based assay for detection of specific DNA sequences has been developed. Lipase from Candida antarctica was conjugated to DNA and captured on magnetic beads in a sandwich assay, in which the binding was dependent on the presence of a specific target DNA. For amplification and to generate a detectable readout the captured lipase was applied to an optical assay that takes advantage of the enzymatic activity of lipase. The assay applies p-nitrophenol octanoate (NPO) as the substrate and in the presence of lipase the ester is hydrolyzed to p-nitrophenolate which has a strong absorbance at 405 nm. The method provides detection a detection limit of 200 fmol target DNA and it was able to distinguish single base mismatches from the fully complementary target.