有机磷农药在水生态系中生物净化机理研究——1.对硫磷的酶解

从氧化塘系统中分离出能降解对硫磷的细菌Pseudomonas sp.代号CTP-01,能将对硫磷分解成对硝基酚和二乙基硫代磷酸酯,并进一步分解对硝基酚。在有Cu++存在的情况下,酶比活可以达到1×104毫微克分子/毫克蛋白/分钟,Cu++对酶有激活作用,并对温度和pH影响有保护作用。对硫磷水解酶反应最适温度为40—50℃,超过50℃活性急剧降低,80℃完全失活。 CTP-01的对硫磷水解酶大部分是同膜片结合状态存在,超声破碎的无细胞酶制剂中,只有37.2%的活力存在于可溶性蛋白部分。       

盐胁迫条件下古菌超氧化物歧化酶增强细菌降解硝基酚

【背景】Burkholderia sp. SJ98利用对硝基酚和2-氯-4-硝基酚为唯一碳源和能源进行生长,通过异源表达嗜盐古菌Haloferax sp. D1227中的超氧化物歧化酶SodA,使菌株SJ98在500 mmol/L NaCl条件下仍具有降解对硝基酚的能力。然而该重组细菌在普通和高盐条件下其降解基因的转录和降解酶比活力的高低,以及该菌在高盐条件下是否还能降解对硝基酚衍生物尚未知晓。【目的】研究Burkholderia sp. SJ98的耐盐上限,观察含有sodA的细菌SJ98在普通和高盐条件下降解对硝基酚和2-氯-4-硝基酚的能力,检测重组菌中pnpA基因的转录和硝基酚单加氧酶的活力。【方法】在添加葡萄糖、对硝基酚或2-氯-4-硝基酚的无机盐培养基(分别含400-800 mmol/L NaCl)或M9培养基(含0和500 mmol/L NaCl)中培养细菌SJ98及其重组菌。通过紫外分光光度计和高效液相色谱法检测菌株生长和底物降解。通过实时荧光定量PCR分别以两种硝基酚为诱导物,检测未添加和添加500 mmol/L NaCl时,硝基酚单加氧酶编码基因pnpA的转录量变化。利用紫外分光光度计分别以两种硝基酚为底物,检测在添加500 mmol/L NaCl时,重组菌和空载体菌的粗酶液中硝基酚单加氧酶对两种底物的活力变化。【结果】野生型菌株SJ98以葡萄糖为碳源生长的NaCl耐受浓度是600mmol/L。未添加NaCl时,重组菌SJ98[pCM-pnpR-PpnpA-sodA-rfp]生长和降解对硝基酚的能力远优于野生菌。添加500 mmol/L NaCl时,重组菌SJ98[pBBR-sodA]仍保持了利用2-氯-4-硝基苯酚底物生长和降解该底物的能力,而空载体菌SJ98[pBBR1MCS-2]的生长和降解能力完全丧失;重组菌SJ98[pBBR-sodA]粗酶液中单加氧酶对于对硝基酚和2-氯-4-硝基酚的活力均约为野生菌的1/3。分别以两种硝基酚为诱导物时,无论是否添加NaCl,重组菌SJ98[pBBR-sodA]中硝基酚单加氧酶编码基因pnpA的转录量比野生型中高出约17-25倍;但添加500 mmol/L NaCl时,pnpA的转录均受到部分抑制。【结论】本研究为利用古菌超氧化物歧化酶对细菌进行改造以提高普通环境和高盐环境中细菌降解硝基芳烃污染物能力的应用提供了潜在的可行性。     

有机磷农药在水生态系中生物净化机理研究——3.对硫磷及其降解产物对栅藻光合作用的影响和模拟藻菌系统中对硝基酚的降解

对硝基酚对栅藻光合放氧有明显抑制作用,半抑制浓度在16毫克/升左右;对硝基酚钠对栅藻光合放氧和CO2同化的抑制作用十分一致,它们的半抑制浓度分别在54毫克/升和52毫克/升左右。实验室证明对硝基酚在水体中主要是由细菌分解,藻类起供氧作用。一旦藻类的光合放氧受到抑制,细菌对对硝基酚的好气性降解能力也消失。对硫磷和二乙基硫代磷酸钾对栅藻光合放氧无明显抑制作用。       

利用a凝集素在酿酒酵母表面展示解脂耶氏酵母脂肪酶Lip2

[目的]将解脂耶氏酵母胞外脂肪酶Lip2展示在酿酒酵母表面,构建全细胞催化剂.[方法]采用PCR方法扩增得到解脂耶氏酵母胞外脂肪酶Lip2成熟肽编码基因LIP2,将其连接到AGA2基因的下游构建表面展示载体pCTLIP2.分别以橄榄油、三丁酸甘油酯和对硝基苯酚棕榈酸酯(pNPP)为底物检测展示的脂肪酶酶活.在此基础上,对野生菌及工程菌的酶学性质进行比较.[结果]展示Lip2的酿酒酵母重组菌株在半乳糖的诱导下,表现出水解橄榄油、三丁酸甘油脂以及pNPP的活性,20℃诱导72h时酶活达到最高,为182 U/g干细胞.对展示的Lip2的酶学性质研究表明,其最适温度为40℃,最适pH为8.0,温度稳定性比自由酶有所提高,50℃温浴4 h后残余酶活为其最大酶活的23.2%.以不同碳链长度的对硝基苯酚酯为底物检测其底物特异性,结果显示其水解C8,C12,C16对硝基苯酚酯活性相近,均远高于对硝基苯酚丁酸酯(C4)的水解酶活.[结论]对于Lip2,a凝集素系统是一个有效的展示系统,利用该系统成功将Lip2展示在酿酒酵母表面,从而构建了酿酒酵母全细胞催化剂,该全细胞催化剂具有良好的潜在应用前景.     

鼠肝色氨酸吡咯酶诱导生成机制的研究 Ⅲ.酶的诱导过程中~(32)P快速标记RNA的变化

本实验观察到在大鼠肝色氨酸吡咯酶的激素和底物诱导过程中都有~(32)P快速标记RNA的出现,它们在氢可地松诱导2小时和在色氨酸诱导3.5小时的比放射性较对照RNA者分别增加100%和60%左右。~(32)P长期标记高聚RNA的变化与快速标记RNA者显然不同,在激素诱导4～6小时和在底物诱导10小时的比放射性始有增高。激素和底物诱导后不同时间提取的~(32)P快速标记RNA的放射性动态变化与其相应RNA诱导TP活性的动态变化呈平行关系,而从~(32)P长期标记活性最高时提取的高聚RNA刺激TP的活力与正常鼠肝RNA刺激TP的活力无显著差别,激素和底物诱导过程中~(32)P快速标记RNA的生成为放线菌素K_2所抑制。去肾上腺大鼠底物诱导2小时和3.5小时也出现~(32)P快速标记RNA,其生成也为放线菌素K_2所抑制。自去肾上腺大鼠底物诱导3.5小时提取的RNA对TP的诱导活性高于相应的正常鼠肝RNA。以上结果说明,在TP的激素和底物诱导过程中所生成的具有体内诱导TP功能的高聚RNA,可能是一种“特异的mRNA”。     

山柰酚通过线粒体凋亡通路诱导三阴性乳腺癌细胞凋亡的机制研究

本文旨在探讨山柰酚对三阴性乳腺癌细胞MDA-MB-231的抑制作用及其可能的分子机制。用不同浓度的山柰酚处理细胞,CCK-8法检测山柰酚对MDA-MB-231和人正常乳腺上皮细胞MCF-10A活力的影响,倒置显微镜观察各组细胞形态变化,克隆形成法检测细胞增殖,流式细胞仪检测细胞凋亡,JC-1染色法检测细胞线粒体膜电位的改变,Western blot检测B细胞淋巴瘤-2(Bcl-2)、Bcl-2相关X蛋白(Bax)、细胞色素C(Cyt C)和细胞周期蛋白D1(CyclinD1)的蛋白表达,比色法检测半胱氨酸天冬氨酸蛋白水解酶-3(Caspase-3)以及半胱氨酸天冬氨酸蛋白水解酶-9(Caspase-9)的活性。结果显示,山柰酚体外可显著抑制MDA-MB-231细胞的增殖,诱导细胞凋亡,且对正常乳腺上皮细胞活力无影响,降低细胞线粒体膜电位,上调Bax、Cyt C的表达,下降Bcl-2和Cyclin D1的表达,增强Caspase-3、Caspase-9活性。结果表明,线粒体凋亡信号通路的激活是山柰酚诱导MDA-MB-231细胞凋亡的途径之一。     

有机磷农药在水生态系中生物净化机理研究——2.CTP-02降解对硝基酚的特性和动力学

从鸭儿湖氧化塘中分离出具有分解对硝基酚能力的细菌Pseudomonas sp.,代号CTP-02。在实验室条件下,细菌培养物降解对硝基酚的速度与时间之间的动力学方程为dc/dt=-K1t-K2,细菌降解对硝基酚的最适温度为35℃,最适pH为7.5。CTP-02菌降解对硝基酚过程中首先发生脱硝基作用。       

利用结构多样性的对硝基苯酚羧酸酯和脂肪醇乙酸酯评估7个枯草芽胞杆菌酯水解酶的指纹图谱

基于GenBank公布的枯草芽胞杆菌168基因组序列,克隆表达了30个预测的酯水解酶基因。结果发现:其中7个酶对对硝基苯酚酯表现出明显的酯水解活力。它们在α/β水解酶家族中分属5个不同的亚家族。通过显色底物和pH指示剂进行的高通量筛选,分别绘制了这7个酶的底物指纹谱。考察了酶催化手性酯水解反应的对映选择性,结果表明:对硝基苄基酯酶PnbA和S-脱乙酰化酶Cah对手性醇的乙酸酯具有较广的底物谱,而PnbA和羧酸酯酶Nap分别对DL-薄荷醇乙酸酯和2-氯-1-苯乙醇乙酸酯/2-萘乙醇乙酸酯有极好的对映选择性(E>200)。此外,发现酯酶YitV催化2-氯-1-苯乙醇乙酸酯水解的反应遵循反-Kazlauskas规则。     

弗氏柠檬酸细菌完整细胞TNT降解酶的性质

弗氏柠檬酸细菌(Cizrobacter freundii)在好氧和兼性好氧条件下具有很强的降解2,4,6-三硝基甲苯(a-TNT)的能力。该菌在牛肉汁培养基中30℃摇床培养10小时,其完整细胞TNT降解酶活力最高。酶反应最适pH为7．2,最适温度为30℃,酶的pH和温度稳定性较佳,在PH 6.0--8.0时,30℃保温12小时,保留活力90％以上,30小时仍有76％剩余活力。作用于a—TNT的米氏常数(Kin)为5印^f,最大反应速度(Vmax)为0．22／zM／mg蛋白／,J、时。金属离子“g’、Hg冲和。U蚌对酶活力有强烈抑制作用,EDTA无明显抑制。底物类似物间一二硝基苯、2,4-二硝基苯酚和对硝基酚(0.3mM)对酶活力也有一定程度的抑制作用。     

利用固定在角叉菜凝胶中的中间埃希氏菌细胞合成L-多巴

将中间埃希氏菌(Escherichia intermedia)细胞用包埋方法固定在角叉菜凝胶中,应用于从邻苯二酚、丙酮酸和氨酶促合成L-多巴。含75mg细胞/克凝胶的制剂保留原酶活性的60～65％。通过对三种底物抑制作用进行观察。看到底物浓度对游离细胞和固定化细胞合成L-多巴初速度的影响几乎相似,在分批反应器中,20小时得到7.8克/升以上的L-多巴(产率是0.39克/升小时)。在初速度条件和分批反应器中,固定在角叉菜凝胶中的细胞合成的L-多巴比固定在聚丙烯酰胺凝胶中的细胞要高。     

THE INSECTICIDAL MATERIAL IN LEAVES OF PLANTS GROWING IN SOIL TREATED WITH PARATHION

After parathion solutions had been watered on to soil around the roots of cabbage plants with leaves infested with Brevicoryne brassicae, Myzus persicae or Pieris brassicae larvae, these leaves showed a toxic effect on the feeding insects. In comparable experiments, Aphis fabae on leaves of broad bean was not affected at dosages that damaged the plants. The effect on the cabbage plants was observed when the parathion was of the highest degree of purity, as shown by chemical tests and its negligible anticholinesterase activity, although it was greater with commercial grade material. It occurred when all possibility of a fumigant action was excluded.
When the roots of wheat plants were treated with solutions of pure parathion the leaf guttation fluid was toxic to Aëdes aegypti larvae and contained an active anticholinesterase. This was shown to be paraoxon; no parathion could be detected in the fluid. The paraoxon was formed rather slowly from the parathion when the roots and leaves of wheat seedlings were immersed in the solution but not in the presence of compost alone.
In plants treated with pure parathion the translocation of the paraoxon formed under the influence of the roots was sufficient to account for the toxic effects produced. With commercial parathion, analogues or isomers present as impurities may also be translocated. Both these sources of systemic poisons should be borne in mind when considering parathion treatment of greenhouse soil in which food crops are to be grown.     

Hydrolysis of organophosphate insecticides by an immobilized-enzyme system.

An enzyme preparation that could detoxify parathion and eight other organophosphate pesticides was covalently bound to either porous glass or porous silica beads. This immobilized-enzyme system was examined for its use in detoxification of pesticides in production wastewaters. The kinetics of parathion hydrolysis were examined at flow rates up to 96 liter/hr and at influent substrate concentrations ranging from 10--250 mg/liter. The enzyme reactor was able to hydrolyze 95% or more of the parathion added to industrial wastewaters generated during its production, thus reducing the effluent parathion concentration to below 500 ppb. Laboratory continuous-flow experiments were conducted for 70 days with industrial wastewater and indicated no loss in immobilized-enzyme activity. The influence of pH, temperature, solvents, and detergents on enzyme stability and activity and enzyme reactor kinetics will be discussed.     

Optical microbial biosensor for detection of methyl parathion pesticide using Flavobacterium sp. whole cells adsorbed on glass fiber filters as disposable biocomponent

An optical microbial biosensor was described for the detection of methyl parathion pesticide. Whole cells of Flavobacterium sp. were immobilized by trapping in glass fiber filter and were used as biocomponent along with optic fiber system. Flavobacterium sp. has the organophosphorus hydrolase enzyme, which hydrolyzes the methyl parathion into detectable product p-nitrophenol. The immobilized microbial biocomponent was disposable, cost-effective and showed high reproducibility and uniformity. The detection of methyl parathion by the use of disposable microbial biocomponent with optical biosensor was simple, single step and direct measurement of very low quantity of the sample. The home made reaction vessel was small and needed only 75 microl of sample. A lower detection limit 0.3 microM methyl parathion was estimated from the linear range (4-80 microM) of calibration plot of organophosphorus hydrolase enzymatic assay. The applicability to synthetic methyl parathion spiked samples was demonstrated.     

Studies of the enzymic mechanism of the metabolism of diethyl 4-nitrophenyl phosphorothionate (parathion) by rat liver microsomes

1. The metabolism of parathion by rat liver microsomes is affected by various enzyme inhibitors in a manner quite typical of the ;mixed-function oxidase' enzyme systems. 2. With many of these inhibitors (p-chloromercuribenzoate, Cu(2+), 8-hydroxyquinoline) the conversion of parathion into diethyl hydrogen phosphorothionate is less inhibited than conversion into diethyl 4-nitrophenyl phosphate (paraoxon). 3. Compounds containing reduced sulphur stimulate the overall metabolism of parathion. However, the conversion of parathion into diethyl hydrogen phosphorothionate is stimulated more than its conversion into paraoxon. 4. The metabolism of parathion to diethyl hydrogen phosphorothionate is also stimulated by EDTA, Ca(2+) and Ba(2+), but these stimulatory effects are not additive. 5. The electron acceptors FAD, riboflavine, menadione and methylene blue exhibit a concentration-dependent differential inhibition of the metabolism of parathion to diethyl hydrogen phosphorothionate and to paraoxon. 6. The concentration of parathion required for the half-maximal rate of production of diethyl hydrogen phosphorothionate is significantly different from the concentration required for half-maximal rate of production of paraoxon. 7. The results are discussed in terms of either two separate enzyme systems metabolizing parathion to diethyl hydrogen phosphorothionate and to paraoxon or two different binding sites for parathion, which share a common electron-transport pathway.     

Microbial biosensor for detection of methyl parathion using screen printed carbon electrode and cyclic voltammetry

Whole cells of recombinant Escherichia coli were immobilized on the screen printed carbon electrode (SPCE) using glutaraldehyde. Recombinant E. coli was having high periplasmic expression of organophosphorus hydrolase enzyme, which hydrolyzes the methyl parathion into two products, p-nitrophenol and dimethyl thiophosphoric acid. Cells immobilized SPCE was studied under SEM. Cells immobilized SPCE was associated with cyclic voltammetry and cyclic voltammograms were recorded before and after hydrolysis of methyl parathion. Detection was calibrated based on the relationship between the changes in the current observed at +0.1 V potential, because of redox behavior of the hydrolyzed product p-nitrophenol. As concentration of methyl parathion was increased the oxidation current also increased. Only 20 μl volume of the sample was required for analysis. Detection range of biosensor was calibrated between 2 and 80 μM of methyl parathion from the linear range of calibration plot. A single immobilized SPCE was reused for 32 reactions with retention of 80% of its initial enzyme activity.     

Purification and characterization of a secreted recombinant phosphotriesterase (parathion hydrolase) from Streptomyces lividans.

A heterologous phosphotriesterase (parathion hydrolase), previously cloned from a Flavobacterium species into Streptomyces lividans, was secreted at high levels and purified to homogeneity. N-terminal analysis revealed that it had been processed in the same manner as the native membrane-bound Flavobacterium hydrolase. The enzyme consisted of a single polypeptide with an apparent molecular weight of 35,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Substrate specificity studies showed Kms of 68 microM for parathion, 46 microM for O-ethyl O-p-nitrophenyl phenylphosphonothioate, 599 microM for methyl parathion, and 357 microM for p-nitrophenyl ethyl(phenyl)phosphinate. Temperature and pH optima were 45 degrees C and 9.0, respectively. The purified enzyme was inhibited by 1 mM dithiothreitol and 1 mM CuSO4. After chelation and inactivation by o-phenanthroline, however, activity could be partially restored by 1 mM CuCl or 1 mM CuSO4. The results showed that the purified recombinant parathion hydrolase has the same characteristics as the native Flavobacterium hydrolase. This system provides a source of milligram quantities of parathion hydrolase for future structural and mechanism studies and has the potential to be used in toxic waste treatment strategies.     

Crystal structure of methyl parathion hydrolase from Pseudomonas sp. WBC-3

Methyl parathion hydrolase (MPH, E.C.3.1.8.1), isolated from the soil-dwelling bacterium Pseudomonas sp. WBC-3, is a Zn(II)-containing enzyme that catalyzes the degradation of the organophosphate pesticide methyl parathion. We have determined the structure of MPH from Pseudomonas sp. WBC-3 to 2.4 angstroms resolution. The enzyme is dimeric and each subunit contains a mixed hybrid binuclear zinc center, in which one of the zinc ions is replaced by cadmium. In both subunits, the more solvent-exposed beta-metal ion is substituted for Cd2+ due to high cadmium concentration in the crystallization condition. Both ions are surrounded by ligands in an octahedral arrangement. The ions are separated by 3.5 angstroms and are coordinated by the amino acid residues His147, His149, Asp151, His152, His234 and His302 and a water molecule. Asp255 and a water molecule serve to bridge the zinc ions together. MPH is homologous with other metallo-beta-lactamases but does not show any similarity to phosphotriesterase that can also catalyze the degradation of methyl parathion with lower rate, despite the lack of sequence homology. Trp179, Phe196 and Phe119 form an aromatic cluster at the entrance of the catalytic center. Replacement of these three amino acids by alanine resulted in a significant increase of K(m) and loss of catalytic activity, indicating that the aromatic cluster has an important role to facilitate affinity of enzyme to the methyl parathion substrates.     

Purification and characterization of a secreted recombinant phosphotriesterase (parathion hydrolase) from Streptomyces lividans.

A heterologous phosphotriesterase (parathion hydrolase), previously cloned from a Flavobacterium species into Streptomyces lividans, was secreted at high levels and purified to homogeneity. N-terminal analysis revealed that it had been processed in the same manner as the native membrane-bound Flavobacterium hydrolase. The enzyme consisted of a single polypeptide with an apparent molecular weight of 35,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Substrate specificity studies showed Kms of 68 microM for parathion, 46 microM for O-ethyl O-p-nitrophenyl phenylphosphonothioate, 599 microM for methyl parathion, and 357 microM for p-nitrophenyl ethyl(phenyl)phosphinate. Temperature and pH optima were 45 degrees C and 9.0, respectively. The purified enzyme was inhibited by 1 mM dithiothreitol and 1 mM CuSO4. After chelation and inactivation by o-phenanthroline, however, activity could be partially restored by 1 mM CuCl or 1 mM CuSO4. The results showed that the purified recombinant parathion hydrolase has the same characteristics as the native Flavobacterium hydrolase. This system provides a source of milligram quantities of parathion hydrolase for future structural and mechanism studies and has the potential to be used in toxic waste treatment strategies.