高产大豆异黄酮糖苷水解酶菌株的发酵工艺研究*

Absidia sp．R是从酒曲中分离出的一株产大豆异黄酮糖苷水解酶活性较高的菌株。该菌最佳产酶条件为：2．5％的麦麸为碳源,1％的硝酸钠为氮源,培养基起始pH为7．0,瓶装量为40mL/250mL,接种量8％,培养温度为30℃,转数为160r／min,培养时间为84h,其酶活力可达到82U／mL。除Cu^2 对该菌产酶有较强的抑制作用外,金属离子对产酶影响不大。     

双酶法制备螺旋藻多肽的工艺研究

选用碱性蛋白酶和木瓜蛋白酶结合的双酶法对螺旋藻蛋白进行水解。其中,对木瓜蛋白酶水解螺旋藻蛋白的工艺进行优化。以水解度为指标,研究了酶解时间、酶与底物比、pH和酶解温度4种因素对酶解反应的影响。在此基础上设计了3因素(加酶量、酶解温度和pH)3水平的响应面试验。结果表明碱性蛋白酶水解螺旋藻蛋白的最佳酶解条件为:加酶量4300 U/g,pH 7.0,酶解温度55℃,酶解时间160 min;木瓜蛋白酶的最佳酶解条件为:酶底比为4.5%,酶解温度60℃,pH 6.5,酶解时间210 min。利用碱性蛋白酶和木瓜蛋白酶结合的双酶法制得的多肽水解度可达32.90%,与单酶法相比,水解度明显提高。     

大豆异黄酮糖苷酶产生菌培养条件优化及转化

将经过筛选的产大豆异黄酮糖苷水解酶的菌株米曲霉3042经过单因子及正交试验,确立了产酶的最适培养基配方为：玉米芯＋麸皮4%,（NH4）2SO40.1%,水扬苷0.01%,KH2PO40.1%,Vc 0.1%,MgSO40.1%.产酶的最佳培养条件为：发酵培养基起始pH 6.0,发酵温度27℃,摇床转速160r/min,发酵时间84 h时酶活力最高.粗提取的大豆异黄酮经发酵液转化后,其结合态含量降低,游离态含量增加.     

诱导蜂房哈夫尼菌产L-赖氨酸脱羧酶条件的研究

用响应面法对蜂房哈夫尼菌（Hafnia alvei）L-赖氨酸脱羧酶产酶诱导条件进行优化。首先通过单因素实验对产酶体系的pH、震荡培养时间、静置培养时间、诱导物添加量和Ⅷ添加量进行优化。在此基础上,用部分因子重复试验筛选出对酶活影响显著的3个因素（静置培养时间,诱导物添加量,VB6添加量）,再通过Box-behnken实验对这三个因素进行优化,得出最优值。最终得到产酶最佳诱导条件为：震荡培养阶段培养基pH6．5,静置培养阶段pH5．5;摇床震荡培养11h后静置培养7．5h,诱导物L一赖氨酸加入量为5．18dL,维生素B6加入量为1．38g／L时酶活最高,达到71．2U／mL,为优化前（1．74u／mL）的41．8倍,在单因素的基础上提高了19％。     

碱性蛋白酶水解大豆分离蛋白制备大豆多肽的工艺条件优化

以大豆分离蛋白为原料,地衣芽胞杆菌产碱性蛋白酶水解大豆分离蛋白,分别从酶浓度、pH值、反应温度和水解时间等因素来研究水解效果,在50℃,pH 10,酶浓度100 U/mL,水解2 h时水解效果最好,水解度达到31.45%。     

响应面法优化豆粕固态发酵工艺的研究

采用SAS 9.1.3中的响应面分析法（中心组合一致精度设计）对影响豆粕固态发酵中蛋白质水解的四个主要因素（料水比,加酶量,发酵时间,接种量）进行了优化,考察了各因素及其交互作用对大豆蛋白水解度的影响。通过模拟二次多项式回归预测模型并建立了影响因素与响应值（水解度）之间的函数关系,即回归方程,根据回归方程寻优得出,当料水比1：1.00,加酶量2.55％,发酵时间65h,接种量1.00％时水解度可达13.3％,且比优化前提高了56％。     

酶促水解大豆分离蛋白动力学模型的研究

本文对AS1.398中性蛋白酶在pH6.9和温度49℃条件下水解大豆分离蛋白的动力学机制进行了研究．结果表明：酶水解速率随水解反呈指数递减．为了解释实验结果,我们提出了如下假设：对底物而言水解反应终为零级反应,水解过程中由于游离酶攻击酶-底物中间络合物而造成的不可逆酶变性是一个二级动力学过程．在此基础上,由实验数据推导得到了描述AS1.398中性蛋白酶催化水解大豆分离蛋白的动力学方程,该方程可用于指导和优化酶解反应实验．     

胃蛋白酶水解绿豆分离蛋白的工艺

选用胃蛋白酶对绿豆分离蛋白进行酶法水解,考察了原料预处理条件、pH、温度、底物浓度等对酶解的影响,结果表明：原料预处理最适条件为沸水浴中90℃处理20min,在37℃、pH1．8、底物质量分数7％、酶量6000U／g条件下酶解180min,水解度（DH％）为19．86％,达到了制备小肽的水解度要求。实验证明,经过水解,绿豆分离蛋白各功能特性得到很好的改善。     

酶解法去除胭脂虫红色素提取液中蛋白工艺研究

本文对酶解胭脂虫体内蛋白工艺过程进行了研究,首先通过实验筛选出了木瓜蛋白酶为酶制剂,重点在单因素实验的基础上,选用了Box—Benhnken响应面分析法,得到了酶解工艺过程优化工艺条件：加酶量为3％、酶解时间为5h、温度为45℃、溶液pH值为5,水解率为4．72％。     

糖化酶酶解米渣纯化米蛋白的工艺

研究了糖化酶酶解米渣纯化米蛋白的实验条件:液固比、酶解时间、pH、温度和酶量。通过正交实验优化了酶解主要条件,得到糖化酶水解米渣最佳条件:液固比5:1,时间3 h,pH 4.0,温度65℃和酶量30 U.g-1。在最佳条件下实验,米蛋白的提取率为81.3%,纯度为76.8%。     

Partial purification and characterization of a soybean beta-glucosidase with high specific activity towards isoflavone conjugates.

A beta-glucosidase with high specific activity towards isoflavone conjugates was purified from soybean [Glycine max] roots by high salt extraction from a low speed centrifugal pellet and subsequent anion and cation exchange chromatography. Purification required stabilization throughout fractionation in 10% glycerol. The enzyme is most likely a dimer (approximate M(r) 165 kDa) with potential subunits of M(r) 80 and/or 75 kDa. The pH and temperature optima are pH 6 and 30 degrees C, respectively. The enzyme was highly heat-stable. Of the various potential effectors examined, silver and mercury ions were the most inhibitory. The IC(50) of silver ions was increased from 140 microM to 14 mM in the presence of 250 microM beta-mercaptoethanol. Glucono-delta-lactone was not strongly inhibitory (IC(50) 24 mM). The activity was highly active against isoflavone conjugates, with a specificity constant 160-1000 fold higher for isoflavone conjugates over the generic chromogenic substrate, p-nitrophenyl beta-glucoside. The enzyme was inactive against the flavonol glycosides tested. The partially purified enzyme had similar K(m) and k(cat) towards 7-O-glucosyl- and 7-O-glucosyl-6"-malonyl-isoflavones, suggesting that it may be able to cleave the esterified glucosyl conjugate. We hypothesize that the enzyme is involved in the release of daidzein and genistein, both of which play central roles in soybean defense.     

酶法破碎裂殖壶菌提取胞内油脂

采用酶法破碎裂殖壶菌提取胞内油脂,进行单因素实验和正交实验优化酶解反应条件,酶解反应的影响因素主次顺序依次为酶用量、温度、时间、pH,最佳酶解工艺参数:55 ℃、pH 9.5、搅拌反应2.5 h、酶用量为菌体生物量的2%.在该条件下,胞内油脂的提取量高达(81.53±0.33) g/L,过氧化值仅为0.15,酸价为0.24.     

固定化重组β-葡萄糖苷酶转化大豆异黄酮的研究

以壳聚糖微球为载体,采用交联-吸附法固定重组β -葡萄糖苷酶.研究考察了该酶的固定化条件及固定化酶转化大豆异黄酮类底物黄豆黄苷的最适反应体系和系统稳定性.结果显示该固定化酶能够有效转化大豆异黄酮的三种糖苷,黄豆黄苷最适转化条件为pH 6.4,45℃.在pH6.4的缓冲液中4℃贮存25 d后,酶活力仍保持85％以上.固定化重组酶在重复使用10批次的情况下,底物转化率仍能保持在85％左右.     

Optimization of conditions for the enzymatic hydrolysis of phytoestrogen conjugates in urine and plasma

Optimal pH, temperature, and concentration of enzyme conditions for the rate of hydrolysis of five isoflavone conjugates (daidzein, O-desmethylangolensin, equol, genistein, and glycitein) and two lignans (enterodiol and enterolactone) from two biological matrices (urine and plasma) were studied using beta-glucuronidase from Helix pomatia. In addition, the use of mixtures of beta-glucuronidase and sulfatase enzymes from different sources was investigated to find enzyme preparations that contained lower amounts of naturally present phytoestrogens. Quantification of aglycones spiked with (13)C(3)-labeled internal standards was carried out by LC-MS/MS. In urine, all of the phytoestrogen conjugates hydrolyzed within 2h under standard hydrolysis conditions (24mul H. pomatia, pH 5, 37 degrees C). Hydrolysis rates were improved at 45 degrees C and by doubling the enzyme concentration and may be used to further reduce hydrolysis times down to 100min. In plasma, a 16-h hydrolysis was required to ensure complete hydrolysis of all conjugates. As with urine, the use of increased temperature or increased enzyme concentration reduced hydrolysis times for most analytes. However, the rate of hydrolysis in plasma was significantly slower than that in urine for all analytes except enterodiol, for which the reverse was true. Neither increased temperature nor increased enzyme concentration increased the rate of hydrolysis of enterolactone. Hydrolysis at pH 6 proved to be detrimental to hydrolysis of phytoestrogen conjugates, especially those in plasma. Other enzyme preparations from different sources, such as beta-glucuronidase from Escherichia coli, were found to contain lower amounts of contaminating phytoestrogens and showed increased enzyme activity for isoflavones, but lower activity for lignans, when used with other sulfatase enzymes. In addition, this involved complicating the analytical procedure through using mixtures of enzymes. Therefore, the use of beta-glucuronidase from H. pomatia combined with an enzyme "blank" to correct for phytoestrogen contamination was shown to be a suitable method for hydrolysis of phytoestrogens.     

大豆籽粒发育过程中异黄酮合成相关酶基因的表达模式与异黄酮积累的相关分析

利用高效液相色谱法和实时定量PCR方法,分别测定了2个异黄酮含量显著差异的大豆品种鲁黑豆2号(LHD2)和南汇早黑豆(NHZ)在子粒发育过程中的异黄酮含量变化以及异黄酮合成相关酶基因的表达模式变化,试图分析异黄酮积累与各基因表达量变化的相关关系。结果表明在大豆子粒发育过程中,异黄酮含量逐渐升高,而不同异黄酮合成相关酶基因的表达趋势不同,CHS7、CHS8、CHR、CHI1A和IFS2的表达趋势与异黄酮积累模式基本一致,而IFS1和CHI1B1的表达趋势与异黄酮积累模式相反。IFR的表达模式在2个大豆品种中存在相反的趋势,在LHD2中与异黄酮组分积累趋势相反,而在NHZ中与异黄酮组分积累趋势相同。结果还表明,同一基因家族中不同基因在子粒发育过程中的表达量也存在差异。查尔酮合酶基因家族中CHS7和CHS8以及查尔酮异构酶基因家族的CHI1A的表达水平相对其他成员较高,异黄酮合酶基因家族中IFS2的表达量显著高于IFS1的表达量,预示这些基因家族在大豆子粒异黄酮积累过程中存在功能分化。此外,各基因表达模式与异黄酮积累的相关分析结果表明,不同基因表达模式与异黄酮积累的相关性在2个品种中也不尽相同。LHD2中CHS7、CHS8和IFS2在子粒发育过程中的表达量变化与不同异黄酮组分呈显著正相关,CHI1B1基因的表达量变化与不同异黄酮组分呈显著负相关。而在NHZ中,IFR在子粒发育过程中的表达量变化与多个异黄酮组分呈显著正相关。这预示了不同大豆品种异黄酮含量差异的潜在遗传基础。各异黄酮合成相关酶基因表达量变化的相关分析表明,在2个品种中,苯丙氨酸水解酶PAL1与4CL,4CL与CHS2以及CHS1与IFS2基因的表达量均呈现显著正相关。表明这些基因可能通过协同作用共同调控异黄酮的合成与积累。这些结果为今后利用基因工程提高大豆异黄酮含量奠定了基础。     

Solubilization of a novel isoflavone glycoside-hydrolyzing β-glucosidase from Lactobacillus casei subsp. rhamnosus

A novel isoflavone glycoside-hydrolyzing β-glucosidase produced by Lactobacillus casei subsp. rhamnosus IFO 3425 was solubilized by ultrasonic disruption of the cells in the presence of 2-mercaptoethanol and sorbitol as stabilizer. The β-glucosidase from L. casei subsp. rhamnosus specifically hydrolyzed soybean isoflavone glycosides, namely, daidzin and genistin, converting them to daidzein and genistein, respectively. By contrast, a commercial preparation of almond emulsin β-glucosidase could not hydrolyze these soybean isoflavone glycosides. The undesirably bitter and astringent isoflavone glycosides in soybean were decomposed for the first time with this novel β-glucosidase, an enzyme which has hitherto been considered difficult to solubilize, produced by a lactic acid bacterium.     

干旱胁迫对苗期大豆异黄酮合成的影响

以不同耐旱性的2个大豆品种(高耐旱JP-6、低耐旱JP-16)为研究材料,采用高效液相色谱和实时荧光定量PCR技术,分析不同时间持续干旱胁迫下,大豆叶片和根系中异黄酮的积累变化及关键酶基因的表达情况.结果表明:大豆根部异黄酮含量显著高于叶部,而异黄酮关键酶基因的表达量则在叶片中更高,耐旱品种JP-6根部的异黄酮积累量更大.随着干旱胁迫持续时间的增加,不同耐旱品种的异黄酮合成与积累变化规律存在显著差异:强耐旱品种JP-6的根和叶中,异黄酮积累量均呈现先下降后升高的趋势;而弱耐旱品种JP-16则相反,异黄酮积累量在不同部位中均呈现先上升后降低的趋势;除JP-6叶中C4H、4CL、IFS2等异黄酮合成上游基因外,其他不同品种、不同部位的关键酶基因表达量均随着干旱胁迫持续时间的增加,呈现先下降后上升的趋势.大豆叶片是异黄酮的主要合成部位,大豆根部也存在少量的异黄酮合成.弱耐旱大豆根部的异黄酮合成和最终积累量均较低,强耐旱品种则较高.根部异黄酮积累量高的大豆品种,其耐旱性更强.     

一种食源性溶栓酶的分离纯化与部分酶学性质的研究

目的对以豆渣为原料,接种纳豆菌的发酵物分离纯化和酶学性质研究。方法采用生理盐水浸提、(NH4)2SO4分级沉淀、Sephadex G-100凝胶层析等纯化步骤,得到层析纯的食源性溶栓酶-纳豆激酶,结果经聚丙烯酰胺凝胶电泳显示为二个组分。酶学性质研究表明,以酪蛋白为底物时,最适反应温度为60℃,最适反应pH为8.0,在pH7~9溶液中,37℃以下基本稳定。体外溶栓作用表明,纳豆激酶溶解纤维蛋白的方式主要是直接溶解,而不是纤溶酶原激活剂。     

The potential of enzyme recycling during the hydrolysis of a mixed softwood feedstock

Despite recent improvement in cellulase enzymes properties, the high cost associated with the hydrolysis step remains a major impediment to the commercialization of full-scale lignocellulose-to-ethanol bioconversion process. As part of a research effort to develop a commercial process for bioconversion of softwood residues, we have examined the potential for recycling enzymes during the hydrolysis of mixed softwood substrate pretreated by organosolv process. We have used response surface methodology to determine the optimal temperature, pH, ionic strength, and surfactant (Tween 80) concentration for maximizing the recovery of bound protein and enzyme activity from the residual substrates after hydrolysis. Data analysis showed that the temperature, pH and surfactant concentration were the major factors governing enzyme desorption from residual substrate. The optimized conditions were temperature 44.4 °C, pH 5.3 and 0.5% Tween 80. The optimal conditions significantly increased the hydrolysis yield by 25% after three rounds of hydrolysis. This bound enzyme desorption combining with free enzyme re-adsorption is a potential method to recover cellulase enzymes and reduce the cost of enzymatic hydrolysis.     

营养保健甘薯汁制备工艺的优化

目的：优化营养保健甘薯汁的制备工艺。方法：本研究以甘薯为原料,在加酶量、作用时间、反应温度、pH及底物浓度五个单因素试验的基础上采用响应面分析法,以甘薯浆中还原糖量为评价指标,对耐高温α-淀粉酶酶解甘薯浆中淀粉的最佳工艺进行了研究,并利用统计学方法建立了耐高温α-淀粉酶酶解甘薯浆中淀粉的二次多项数学模型。结果：最佳酶解条件为：加酶量480U／g,作用时间90min,反应温度77℃,pH值6．0,底物浓度2．6g／10ml。结论：在最佳酶解条件下,甘薯中还原糖最大估计值为13．97345％。实测值为（13．968±0．05）％。