毕赤酵母表面展示南极假丝酵母脂肪酶B全细胞催化合成葡萄糖月桂酸酯

利用表面展示南极假丝酵母脂肪酶B(Candida antarctica lipase B,CALB)的毕赤酵母细胞为全细胞催化剂,以葡萄糖为酰基受体,月桂酸为酰基供体,在非水相体系中催化合成糖酯。用硅胶柱层析对产物进行初提,再用制备液相色谱进一步分离纯化,并用高效液相色谱-质谱鉴定纯品性质。对该酶法合成糖脂反应体系进行了优化,其中考察了有机溶剂种类、复合溶剂体系中二甲基亚砜(DMSO)体积百分比、酶量、底物摩尔比、水活度和温度等几个影响酯化反应的因素。结果表明:在5mL反应体系中,以叔戊醇/二甲基亚砜(DMSO30%,V/V)为反应介质,添加初始水活度为0.11的全细胞催化剂0.5g,葡萄糖0.5mmol/L,月桂酸1.0mmol/L,60°C下反应72h后,葡萄糖月桂酸单酯的转化率达到48.7%。     

酵母表面展示脂肪酶合成己二酸二异辛酯

展示酶的酵母细胞既具有固定化酶的优点,又有制备简单、成本较低的特点.采用表面展示南极假丝酵母脂肪酶B (Candida antarctica lipase B,CALB)的毕赤酵母细胞催化合成己二酸二异辛酯(Diisooctyl adipate,DIOA),对该反应体系进行优化,并实现了初步工艺放大制备.经条件优化后,在10mL反应体系中,DIOA的产率可达85.0％.该工艺放大到200mL反应体系时,DIOA产率可达97.8％.经减压蒸馏,DIOA纯度可达到98.2％.该酵母表面展示脂肪酶在合成绿色润滑油己二酸二异辛酯中具有良好应用前景.     

南极假丝酵母脂肪酶B的酿酒酵母表面展示及其催化己酸乙酯的合成

从南极假丝酵母(Candida antarctica)基因组克隆得到南极假丝酵母脂肪酶B(Candida antarctica Lipase B, CALB)全基因片段, 利用连接肽celA Linker将CALB与酿酒酵母细胞表面展示蛋白a-凝集素的C端连接融合, 构建表面展示载体pICAS-celAL-CALB, 转化酵母后获得重组酵母菌Saccharomyces cerevisiae pICAS-celAL-CALB。该重组酵母菌经葡萄糖诱导表达及分析, 表明CALB已在酿酒酵母细胞表面成功展示, 水解活力达26.26 u/(g·dry cell)。重组酵母菌经冻干能有效地实现在非水相中全细胞催化己酸和乙醇酯化合成己酸乙酯。反应物己酸与乙醇的摩尔比为1:1.25, 己酸乙酯的产率为98.0%, 具有较好的操作稳定性。     

南极假丝酵母脂肪酶B的酿酒酵母表面展示及其催化己酸乙酯的合成

从南极假丝酵母(Candida antarctica)基因组克隆得到南极假丝酵母脂肪酶B(Candida antarctica Lipase B, CALB)全基因片段, 利用连接肽celA Linker将CALB与酿酒酵母细胞表面展示蛋白a-凝集素的C端连接融合, 构建表面展示载体pICAS-celAL-CALB, 转化酵母后获得重组酵母菌Saccharomyces cerevisiae pICAS-celAL-CALB。该重组酵母菌经葡萄糖诱导表达及分析, 表明CALB已在酿酒酵母细胞表面成功展示, 水解活力达26.26 u/(g·dry cell)。重组酵母菌经冻干能有效地实现在非水相中全细胞催化己酸和乙醇酯化合成己酸乙酯。反应物己酸与乙醇的摩尔比为1:1.25, 己酸乙酯的产率为98.0%, 具有较好的操作稳定性。     

利用α凝集素在毕赤酵母表面展示脂肪酶

目的:将南极假丝酵母脂肪酶B(CALB)通过α凝集素3’末端功能区域展示在毕赤酵母表面。方法:采用PCR方法扩增得到CALB成熟肽编码基因,将其连接到α凝集素3’末端的上游再与穿梭载体pPIC9K连接,构建表面展示载体p KNS-CALB。检测其水解活力和相关酶学性质。结果:展示CALB的毕赤酵母在甲醇的诱导下,表现出水解活性,最高可达382 U/g干细胞。对展示CALB的酶学性质研究表明:其最适温度为45℃,最适pH为8.0,60℃水浴4 h后残留酶活力高于最大酶活力的50%,其水解对硝基苯酚丁酸酯的酶活力最高。结论:利用α凝集素成功将CALB展示于毕赤酵母表面,酶活力有较大提高。     

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.     

酵母细胞表面展示技术及其在非水相酶催化合成中的应用

酵母展示技术是将外源蛋白与酵母细胞壁蛋白融合,并将外源蛋白表达在酵母细胞表面。酵母展示技术已广泛应用于各种功能蛋白的表达及筛选。以下重点介绍酵母展示技术在脂肪酶展示体系构建及其在脂肪酸甲酯、短链芳香酯及糖酯生物合成中的应用。     

毕赤酵母表面展示棘孢曲霉β-葡萄糖苷酶催化合成APG的工艺条件优化

使用毕赤酵母细胞表面展示棘孢曲霉的β-葡萄糖苷酶作为全细胞催化剂,以葡萄糖为底物,在水-醇双相体系中逆水解合成C6-C10烷基糖苷。讨论了含水量、葡萄糖添加量、全细胞催化剂添加量、乙酸-乙酸钠缓冲液pH值和温度等主要因素对反应的影响,并与商品酶苦杏仁β-葡萄糖苷酶、Novozym188进行比较。结果表明,Novozym188不适合逆水解合成APG,苦杏仁β-葡萄糖苷酶反应所需时间短,但最终转化率不如全细胞催化剂。在5 mL反应体系中,合成HG的最优条件:葡萄糖0.1 g,全细胞催化剂0.05 g,10%pH 3.0 buffer;合成OG的最优条件:葡萄糖0.2 g,全细胞催化剂0.05 g,15%pH3.0 buffer;合成DG的最优条件:葡萄糖0.2 g,全细胞催化剂0.2 g,20%pH 3.0 buffer;放置55℃200 r/min恒温振荡器中,反应时间为72 h,HG和DG的最大产率分别为11.69%和3.58%,而OG的产率则在96 h到达最大值6.34%。     

疏棉状嗜热丝孢菌脂肪酶在毕赤酵母中的表面展示及酶学性质

【目的】构建疏棉状嗜热丝孢菌脂肪酶(Thermomyces lanuginosus lipase,TLL)在毕赤酵母GS115中的细胞表面展示体系,筛选展示成功且酶活力及展示率较高的重组子作为全细胞催化剂,并研究其酶学性质。【方法】克隆TLL基因tll,以酿酒酵母细胞壁蛋白Sed1p为锚定蛋白,构建表面展示载体pPICZαA-TLS。重组载体经SacⅠ线性化后转入毕赤酵母GS115中,经三丁酸甘油酯平板检测及摇甁发酵筛选获得高酶活力的毕赤酵母重组子,采用抗FLAG标签一抗和R-PE荧光素标记的二抗处理细胞后,进行荧光显微镜检测和流式细胞仪分析,并考察全细胞催化剂的最适反应温度和pH、金属离子耐受性等酶学性质。【结果】成功构建TLL毕赤酵母细胞表面展示体系,筛选到1株具有三丁酸甘油酯和橄榄油水解活力的克隆子,经1%的甲醇诱导发酵120 h后,水解橄榄油酶活力达257.8 U/g干细胞。经抗体处理后的重组菌发酵细胞在荧光显微镜下呈现强烈的红色荧光,流式细胞仪分析结果也证实脂肪酶被成功展示在酵母细胞表面,展示率达98.36%。展示的TLL作为全细胞催化剂水解对硝基苯酚丁酸酯(pNPB)的最适温度为30℃,最适pH为8.0,且具备良好的热稳定性和有机溶剂耐受性;K+、Ca2+、Mg2+对其有微弱的激活作用,Mn2+、Ni2+则有微弱的抑制作用,Cu2+的抑制作用较强,而EDTA、SDS、Tween 20对酶活力影响不明显。【结论】首次将TLL脂肪酶成功展示在毕赤酵母细胞表面,获得具有较高水解活力和良好酶学特性的全细胞催化剂,为表面展示TLL脂肪酶的规模化应用奠定了技术基础。     

毕赤酵母Gpn12异戊烯基转移酶NovQ催化合成MK-3

对异戊烯基转移酶NovQ在毕赤酵母Gpn12异源表达过程中诱导剂甲醇添加量进行了探究,并以毕赤酵母Gpn12全细胞为酶源,以甲萘醌、异戊烯醇为前体,催化合成维生素K2(MK-3)。每24 h添加2%甲醇时,NovQ表达量提高约36%。考察摇瓶中初始pH、温度、甲醇添加量、前体(甲萘醌、异戊烯醇)添加量、催化时间、十六烷基三甲基溴化铵(CTAB)添加量等7个因素对Gpn12全细胞催化合成MK-3的影响,发现催化温度、甲萘醌添加量、催化时间影响显著,对3个显著因素进行响应面优化得出催化条件为:催化温度31.56℃,甲萘醌添加量295.54 mg/L,催化时间15.87 h,优化后的摇瓶MK-3产量达到98.47 mg/L,与响应面预测结果一致,较优化前对照组提高了35%。在30 L发酵罐进行生物催化实验,催化时间24 h,细胞催化剂浓度220 g(干重)/L,MK-3产量达到189.67 mg/L。该方法为Gpn12规模化生产MK-3奠定了一定的基础。     

Variable product specificity of microsomal dehydrodolichyl diphosphate synthase from rat liver

Several detergents activated microsomal dehydrodolichyl diphosphate synthase of rat liver, but the chain length of products shifted downward from C90 and C95 with increasing concentration of the detergents. Maximum activation was observed at the concentration of 2% Triton X-100, 30 mM octyl glucoside, 30 mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate, and 10 mM deoxycholate with the product chain length being C80-C85, C65-C75, C70-C75, and C55-C65, respectively. The activity of Triton X-100 solubilized enzyme was decreased by asolectin, phosphatidylethanolamine, and phosphatidylcholine. The chain lengths of products formed in the presence of these phospholipids were C85 and C90. In the presence of both phosphatidylcholine and Mg2+ the solubilized enzyme was able to produce C90 and C95 dehydrodolichyl diphosphates like native microsomal enzyme. Microsomal enzyme preparations from rat liver, brain, and testis catalyzed the formation of dehydrodolichyl diphosphates with the same chain lengths as those of the natural dolichols occurring in individual tissues. The chain length distribution of dehydrodolichyl products by (rat liver) microsomes also depended on the concentration of substrates. Not only did increasing the concentration of isopentenyl diphosphate lead to longer chain product, but decreasing that of farnesyl diphosphate increased product chain length.     

The acyl-CoA oxidases from the yeast Yarrowia lipolytica: characterization of Aox2p

One of the acyl-CoA oxidases from the yeast Yarrowia lipolytica, acyl-CoA oxidase 2 (Aox2p), has been expressed in Escherichia coli as an active, N-terminally tagged (His)(6) fusion protein. The specific activity of the purified enzyme, containing FAD, was 19.7 micromolmin(-1)mg(-1) using myristoyl-CoA as substrate. Using substrates with different chain lengths and different substituents, its kinetic properties were further analyzed. Straight-chain acyl-CoAs, with a chain length of 10-14C, are well oxidized, reflecting the properties of Aox2p as deduced from in vivo studies. Acyl-CoAs containing more than 14C were also desaturated, if their concentration was below 25 microM or if proteins capable of binding these CoA-esters, such as albumin or beta-casein, were added to the assay. These long-chain acyl-CoAs, although poor substrates, acted as competitors for the short- and medium-chain substrates. Compared to palmitoyl-CoA, activity toward hexadecadioyl-CoA, containing a omega-carboxy group, was similar. Taken together, these data suggest that micelles of long-chain acyl-CoAs are able to bind and inhibit Aox2p. The enzyme was also active toward acyl-CoA-esters containing a 2-methyl group, but only the 2S isomer was recognized.     

Rat butyrylcholinesterase-catalysed hydrolysis of N-alkyl homologues of benzoylcholine

The purpose of this work was to study the catalytic properties of rat butyrylcholinesterase with benzoylcholine (BzCh) and N-alkyl derivatives of BzCh (BCHn) as substrates. Complex hysteretic behaviour was observed in the approach to steady-state kinetics for each ester. Hysteresis consisted of a long lag phase with damped oscillation. The presence of a long lag phase, with no oscillations, in substrate hydrolysis by rat butyrylcholinesterase was also observed with N-methylindoxyl acetate as substrate. Hysteretic behaviour was explained by the existence of two interconvertible butyrylcholinesterase forms in slow equilibrium, while just one of them is catalytically active. The damped oscillations were explained by the existence of different substrate conformational states and/or aggregates (micelles) in slow equilibrium. Different substrate conformational states were confirmed by 1H-NMR. The K(m) values for substrates decreased as the length of the alkyl chain increased. High affinity of the enzyme for the longest alkyl chain length substrates was explained by multiple hydrophobic interactions of the alkyl chain with amino acid residues lining the active site gorge. Molecular modelling studies supported this interpretation; docking energy decreased as the length of the alkyl chain increased. The long-chain substrates had reduced k(cat) values. Docking studies showed that long-chain substrates were not optimally oriented in the active site for catalysis, thus explaining the slow rate of hydrolysis. The hydrolytic rate of BCH12 and longer alkyl chain esters vs. substrate concentration showed a premature plateau far below V(max). This was due to the loss of substrate availability. The best substrates for rat butyrylcholinesterase were short alkyl homologues, BzCh - BCH4.     

Properties of unprimed poly(A)-poly(U) synthesis by Caulobacter crescentus RNA polymerase.

Some properties of unprimed poly(A)-poly(U) synthesis by DNA-dependent RNA polymerase from Caulobacter crescentus were examined. The reaction required ATP and UTP as substrates and manganese as a divalent cation. Rifampicin completely inhibited the reaction at a concentration of 1 micron/ml, and the enzyme catalyzed the polymer synthesis well regardless of the presence of GTP, CTP or both. The chain length of the poly(A)-poly(U) synthesized was about one hundred base pairs, as estimated from a sedimentation velocity and the molar ratio of [3H]AMP to [gamma-32P]ATP incorporated into the poly(A)-poly(U). The reaction was dependent on the square of the enzyme concentration and the enzyme dimers formed complexes with poly(A)-poly(U) during the reaction.     

Characterization of a cellodextrin glucohydrolase with soluble oligomeric substrates: experimental results and modeling of concentration-time-course data

A previously isolated cellodextrin glucohydrolase (beta-glucosidase) from Trichoderma reesei QM 9414 is characterized using beta-1,4-glucose oligomers with defined degrees of polymerization as soluble substrates. The enzyme splits off glucose units from the nonreducing chain ends of cellooligomers. Besides this hydrolytic activity there is also evidence for transfer activity depending on the concentration and degree of polymerization of substrates. Concentration-time-course data have been gathered for the degradation of cellobiose, cellotriose, cellotetraose, cellopentaose, and cellohexaose covering a wide range of enzyme and substrate concentrations. A Michaelis-Menten type kinetic model has been developed, which is able to satisfactorily describe the complex system of parallel and series reactions during the conversion of oligomers to glucose. The only kind of inhibition considered is competitive inhibition by the final product glucose. The model takes into account the formation of multiple enzyme-substrate complexes and is limited to those conditions, in which no transglucosylation products are observed. Cellodextrins with higher degrees of polymerization are found to be better substrates for this enzyme than is the dimer cellobiose.     

豇豆初生叶多胺氧化酶的催化特性

从豇豆幼苗 (6d苗龄 )初生叶提纯得到的多胺氧化酶 (EC 1 .4.3 .6 )属于二胺氧化酶 ,最有效的底物是 1 ,4 二胺丁烷 (腐胺 )、1 ,5 二胺戊烷 (尸胺 )、1 ,6 二胺己烷、1 ,1 0 二胺癸烷等α 二胺 ,其催化活性随二胺类底物碳链的增长而相应减弱。豇豆多胺氧化酶对亚精胺和精胺也具有较高的催化活性。另外 ,底物腐胺和尸胺的浓度超过 2mmol/L或亚精胺和精胺浓度超过 3mmol/L时会对酶活性有抑制效应。以腐胺和尸胺为底物时 ,酶的最适 pH约为7.0 ,而以亚精胺和精胺为底物时其最适pH为 6 .5。该酶的催化活性还随反应介质的离子强度增加而降低。K ,Ca2 和Mg2 (皆为 1 0mmol/L)对酶活性无明显抑制作用 ,而同样浓度的Mn2 ,Zn2 ,Fe2 ,Co2 和Cd2 则对酶活性有不同程度的抑制作用。金属螯合剂EDTA(1 0mmol/L)和腺苷蛋氨酸脱羧酶抑制剂甲基乙二醛 双脒腙 (0 .1mmol/L)可抑制酶活性约 80 % ,而铜结合剂KCN(1 .0mmol/L)、羰基试剂羟胺 (0 .1mmol/L)和氨基胍 (0 .1mmol/L)可导致该酶完全失活     

Kinetic analysis of the mechanism of insulin degradation by glutathione-insulin transhydrogenase (thiol: protein-disulfide oxidoreductase).

Kinetic studies have been made with glutathione-insulin transhydrogenase, an enzyme which degrades insulin by promoting cleavage of its disulfide bonds via sulfhydryl-disulfide interchange. The degradation of 125I-labeled insulin by enzyme purified from beef pancreas was studied with various thiol-containing compounds as cosubstrates. The apparent Km for insulin was found to be a function of the type and concentration of thiol; values obtained were in the range from 1 to 40 muM. Lineweaver-Burk plots for insulin as varied substrate were linear, whereas those for the thiol substrates were nonlinears: the plots for low molecular weight monothiols (GSH and mercaptoethanol) were parabolic; those for low molecular weight dithiols (dithiothreitol, dihydrolipoic acid, and 2,3-dimercaptopropanol) were apparently linear modified by substrate inhibition; and the plots for protein polythiols (reduced insulin A and B chains and reduced ribonuclease) were parabolic with superposed substrate inhibition. The nonparallel nature of the reciprocal plots for all substrates shows that the enzyme does not follow a ping-pong mechanism. Product inhibition studies were performed with GSH as thiol substrate. Oxidized glutathione was found to be a linear competitive inhibitor vs. both GSH and insulin. The S-sulfonated derivative of insulin A chain was also linearly competitive vs. both substrates. Inhibition by S-sulfonated B chain was competitive vs. insulin; the data eliminated the possibility that this derivative was uncompetitive vs. GSH. Experiments with the cysteic acid derivatives of insulin A and B chains similarly excluded the possibility that these were uncompetitive vs. either substrate. These inhibition studies indicate that the enzyme probably follows a randdom mechanism.     

The enzyme activity of bovine adrenocortical cytochrome P-450 producing pregnenolone from cholesterol: Kinetic and electrophoretic studies on the reactivity of hydroxycholesterol intermediates

Electrofocusing of a highly-purified preparation of bovine adrenocortical cytochrome P-450(scc) showed a single peak of enzyme activity at pH 6.8, when either cholesterol, [20S]-20-hydroxycholesterol, [22R]-22-hydroxycholesterol or [20R, 22R]-20, 22-dihydroxycholesterol was used as the substrate for the side chain cleavage reaction. The formation of pregnenolone from these hydroxycholesterols was inhibited by [20R, 22S]-20, 22-epoxycholesterol similarly in a competitive manner and the Ki value for the epoxide was found to be 12–15 μM for all these substrates. When one of the above mentioned substrates was incubated in a concentration sufficient for maximal reaction velocity, the addition of another hydroxycholesterol did not result in further increase of pregnenolone production. These results support the assumption that a single species of enzyme catalyzes all the three steps of the reaction, i.e., 20-hydroxylation, 22-hydroxylation and cleavage of carbon chain between carbon-20 and carbon-22.     

Mechanistic studies of the long chain acyl-CoA synthetase Faa1p from Saccharomyces cerevisiae

Long chain acyl-CoA synthetase (ACSL; fatty acid CoA ligase: AMP forming; EC 6.2.1.3) catalyzes the formation of acyl-CoA through a process, which requires fatty acid, ATP and coenzymeA as substrates. In the yeast Saccharomyces cerevisiae the principal ACSL is Faa1p (encoded by the FAA1 gene). The preferred substrates for this enzyme are cis-monounsaturated long chain fatty acids. Our previous work has shown Faa1p is a principal component of a fatty acid transport/activation complex that also includes the fatty acid transport protein Fat1p. In the present work hexameric histidine tagged Faa1p was purified to homogeneity through a two-step process in the presence of 0.1% eta-dodecyl-beta-maltoside following expression at 15 degrees C in Escherichia coli. In order to further define the role of this enzyme in fatty acid transport-coupled activation (vectorial acylation), initial velocity kinetic studies were completed to define the kinetic parameters of Faa1p in response to the different substrates and to define mechanism. These studies showed Faa1p had a Vmax of 158.2 nmol/min/mg protein and a Km of 71.1 microM oleate. When the concentration of oleate was held constant at 50 microM, the Km for CoA and ATP were 18.3 microM and 51.6 microM respectively. These initial velocity studies demonstrated the enzyme mechanism for Faa1p was Bi Uni Uni Bi Ping Pong.     

An alcohol acyl transferase from apple (cv. Royal Gala), MpAAT1, produces esters involved in apple fruit flavor

Apple flavor is characterized by combinations of ester compounds, which increase markedly during fruit ripening. The final step in ester biosynthesis is catalyzed by alcohol acyl transferases (AATs) that use coenzyme A (CoA) donors together with alcohol acceptors as substrates. The gene MpAAT1, which produces a predicted protein containing features of other plant acyl transferases, was isolated from Malus pumila (cv. Royal Gala). The MpAAT1 gene is expressed in leaves, flowers and fruit of apple. The recombinant enzyme can utilize a range of alcohol substrates from short to medium straight chain (C3-C10), branched chain, aromatic and terpene alcohols. The enzyme can also utilize a range of short to medium chain CoAs. The binding of the alcohol substrate is rate limiting compared with the binding of the CoA substrate. Among different alcohol substrates there is more variation in turnover compared with K(m) values. MpAAT1 is capable of producing many esters found in Royal Gala fruit, including hexyl esters, butyl acetate and 2-methylbutyl acetate. Of these, MpAAT1 prefers to produce the hexyl esters of C3, C6 and C8 CoAs. For the acetate esters, however, MpAAT1 preference depends upon substrate concentration. At low concentrations of alcohol substrate the enzyme prefers utilizing the 2-methylbutanol over hexanol and butanol, while at high concentrations of substrate hexanol can be used at a greater rate than 2-methylbutanol and butanol. Such kinetic characteristics of AATs may therefore be another important factor in understanding how the distinct flavor profiles of different fruit are produced during ripening.