一株产碱性蛋白酶菌株的选育及其发酵条件的研究

从土壤中分离到的553株芽孢杆菌中选出一株产蛋白酶活力较高菌株,经紫外线和亚硝基胍诱变,获得一株产碱性蛋白酶的菌株,酶活力可达10000u／m1,此菌株经鉴定为地衣状芽孢杆菌(Bacillus licheniformis)。适宜的发酵条件：培养基由6％玉米粉(山芋粉或葡萄糖),4％豆饼粉(或其水解液),Na,HP0．·12Hz0 0．4％,KH：P0·0．03％,Na zc0,0．1％组成,pH7．O,37℃旋转摇床振荡培养{2一q6小时。酶作用的最适条件：60℃,pH9．0一10．5,在pH6．0—10．5范围内稳定。酶受DFP抑制。     

根瘤菌4012a菌株产细胞分裂素发酵条件的研究

用酶标免疫检测法研究了根瘤菌4012a菌株细胞分裂素发酵的适宜培养基和培养条件。结果表明,其最佳培养基为（g／L）：葡萄糖10.0,（NH4）2SO41.0,K2HPO4·3H2O0．6,MgSO4·7H2O0.1,CaCl2·2H2O0.4,FeCI3·6H2O0．04,Na2MoO4·2H2O0．1mg／L,泛酸钙100μg／L,腺漂吟200mg／L。该菌株在150r／min的旋转摇床上27℃振荡培养96h,发酵液中细胞分裂素产量可达908μg／L,生物活性（萝卜子叶扩大法）为1mg／L激动素当量。     

碱性蛋白酶产生菌的筛选及发酵条件考查

从土壤中分离到的167株芽胞杆菌中选出一株高产、稳产碱性蛋白酶菌株A4－3（嗜碱性枯草芽胞杆菌）。该菌株最适产酶条件为（g／100ml）：蔗糖6．0;豆饼水解液10.0;Na2CO31．0;起始pH9．5。在该条件下,经37℃振荡培养48h,酶活力达2612u／ml。     

地衣芽孢杆菌碱性蛋白酶的研究：I.碱性蛋白酶高产菌的筛选及产酶条件初探

从成都佳丰食品厂等处采集的样品中平板分离初筛到１２４株碱性蛋白酶产生菌,进一步复筛出一株高产,且稳定的碱性蛋白酶产生菌株Ｂ．Ｌ．ＪＦ－ｌｄ初步鉴定为地衣芽孢杆菌（Ｂａｃｉｌｌｕｓｌｉｃｈｅｎｉｆｏｒｍｉｓ）。该菌的最适产酶条件为：培养基（％）为麦芽糖７．５,酵母膏３,ＮａＣｌ０．５,Ｋ２ＨＰＯ４·３Ｈ２Ｏ０．５３,ＮａＨ２ＰＯ４·２３Ｈ２Ｏ０．０３,Ｎａ２ＣＯ３０．０５６,ＭｎＳＯ４ｌ×１０＾－４     

根霉植酸酶的研究──Ⅰ.菌株的分离筛选及发酵条件研究

从21个土样和15株产酶菌株中筛选到1株产酶能力较强的菌株——根霉（Rhizopussp.）MR020。其优化培养基组成（％）：大米粉2.0,干酪素0．05,（NH4）2SO41.0,MgSO4·7H2O0.05,FeSO4·7H2O0.01,pH5.0。其振荡培养条件：培养基装最25ml／250ml三角瓶,用培养8天、浓度为1×107个／ml的孢子悬液接种1ml,于30℃,150r／min振荡培养108h产酶量最高达4000u/ml。     

重离子诱变技术选育碱性蛋白酶高产菌株

从采集的土壤样品中分离筛选出一株碱性蛋白酶产生菌G-41,经16S rRNA分子鉴定为芽孢杆菌属菌株。该菌株在发酵培养基中能产生较高产量的胞外碱性蛋白酶(1.7×104U/mL)。以G-41为出发菌株,对其进行重离子辐照诱变处理,获得突变株G-41-68,将该突变株再次经重离子诱变,从大量突变株中筛选出碱性蛋白酶高产菌株15Gy-54,其酶活力达到6.22×104U/mL。与出发菌株相比较,突变株G-41-68和15Gy-54的酶活力分别提高了1.58倍和2.65倍。对突变株15Gy-54的发酵条件进行了优化研究,结果表明,该菌株的碱性蛋白酶活力得到进一步提高,达到7.18×104U/mL,其最适发酵条件为:培养基(g/100mL)为胰蛋白胨1、酵母膏0.5、乳糖5、Na2HPO4·12H2O0.4、KH2PO40.03、Na2CO30.1、MgSO40.0481(4×10-3mol/L)、pH8.0,培养温度41℃,振荡培养时间42-48h。实验结果表明,重离子辐照诱变技术是一种非常有效的微生物诱变育种新技术。     

嗜碱性芽孢杆菌碱性蛋白酶的研究II.诱变株选育及产酶条件

嗜碱性的短小芽孢杆菌R115(Alkaliphilic Bacillus pumilus)经0．4mg／ml亚硝基胍和0.4μg／ml利福平处理,获得一株具有高产稳产碱性蛋白酶的变异株(B45),产酶活力由2803μ／ml提高到6000u／ml(28℃测定),该诱变株的最适产酶条件为起始pH10．5-11．0,温度30—35℃,培养时间52—54b。0．4-0．6％K2HPO4．可增加酶的产量。     

短小芽孢杆菌碱性蛋白酶的提纯和性质的研究

由短小芽孢杆菌(Bacillus pumilus)209产生的胞外碱性蛋白酶的粗酶制剂(5×10 4u／g),经硼砂NaOH缓冲液抽提,硫酸铵沉淀,Sephadex G一25脱盐,DEAE-纤维素柱层析,冷冻干燥获得部分纯化的酶。纯酶的活力为199x10u/g,比活力提高2,6倍。此酶的最适pH8．5—9．0,在pH6一10之间稳定,因此是属于微碱性蛋白酶“’。最适温度为50℃,在50℃以下稳定,在60℃处理10分钟活力损失95％。0.003村c丑件的存在对酶的热稳定性和pH稳定性均有显著提高。Ag+,Cu2+,Fe2+,Hg+,Zn2+ 对酶有抑制作用;Mn2+有明显的激活作用;1×10-3M的PCMB,IAA,O-PTH,PMSF对活力无影响;1×10-3M EDTA对酶有30％的抑制作用;在40℃用NBS(1×10-4M)、DFP(2．5mM)对醢进行10分钟处理,酶活力完全损失。此酶能水解多种天然蛋白,如酪蛋白、血红蛋白、蛇毒蛋白等,不水解鱼精蛋白和溶菌酶。以酪蛋白为底物测得的km值为0．66×10-2g／ml。在pH7．3进行圆盘凝胶电泳,虽然呈现九条带,但均具有大小不等的蛋白酶活力。     

一株海洋细菌产碱性蛋白酶的研究

对1株产碱性蛋白酶的海洋细菌Pseudomonas sp.7-11发酵产生碱性蛋白酶的条件和酶的调控机制进行了初步研究。结果显示,7－11为好氧菌,具有嗜低温特性,且适宜在偏碱性的条件下生长并产酶,该菌产生碱性蛋白酶表现出初级动力学持征;酷蛋白培养基适合菌株产酶;K^ 对于菌株产酶有关键作用;复合氨基酸对产酶有抑制作用;初步显示,7－11产生蛋白酶受诱导及阻遏两种方向的调控。     

少根根霉菌株发酵生产纤溶酶条件的研究

发酵条件优化可提高少根根霉菌株8B所产纤溶酶的活性。使用单因素试验和正交试验确定该茵发酵产酶的最佳条件。试验确定最优化发酵条件,培养基：麸皮水5g／L,尿素5g／L,胰蛋白胨0．5g／L,K2HPO4·3H2O 0．3g／L,MgSO4·7H2O 0.15g／L,pH5.5,摇床转速160r／min,30℃发酵56h。在此优化条件下培养,8B产纤溶酶活力达到345．41U／mL,是初始培养基发酵产酶活力的7．52倍。     

包衣微丸型碱性蛋白酶的制备

开发了一种包衣微丸型碱性蛋白酶的制备工艺,结果表明:30 L发酵中罐发酵50 h比酶活可达4.26×104 U/mL,发酵液经絮凝处理、板框压滤、膜浓缩后可制成酶活达300 000 U/mL的酶浓缩液.经流化后制得含酶颗粒,再包裹薄层后,得包衣微丸型碱性蛋白酶.对制备的包衣微丸型碱性蛋白酶的稳定性、去污效果等指标进行了评估.制备的包衣微丸型碱性蛋白酶产品在严苛条件下的稳定性与国外产品( Savinase 8.0T、PuraFast 2000HS)相当,产品暴露在37℃、75％湿度下8周后仍可保持74％的酶活力,产品的去污效果优于国外产品.制备的包衣微丸型碱性蛋白酶颗粒大小均匀,流动性和分散性好,对外界高温、高湿等不良环境具有很强的抵抗能力,适于工业化生产.     

Immobilization of alkaline protease on nylon

The parameters involved in immobilization of alkaline protease on nylon using glutaraldehyde as coupling agent and the characteristics of the immobilized enzyme were investigated. Optimum temperature and pH of both free and immobilized enzyme for the degradation of protein was found. Immobilized enzyme showed better thermal stability than the free enzyme. The reusability and storage stability of the immobilized enzyme was also studied.     

Extracellular alkaline protease of newly isolatedRhizopus oryzae

Summary A fungal isolate identified asRhizopus oryzae, produces an extracellular alkaline serine protease. Maximum protease formation was after six days in shake flask culture at two different conditions of pH and temperature optimum (pH 5 at 30°C and pH 10 at 37°C). AgNO₃ and Tween 80 increased protease synthesis. The enzyme is stable between pH 3 and pH 11 and has a temperature optimum of 60°C.     

Laundry detergent compatibility of the alkaline protease from Bacillus cereus

The endogenous protease activity in various commercially available laundry detergents of international companies was studied. The maximum protease activity was found at 50 degrees C in pH range 10.5-11.0 in all the tested laundry detergents. The endogenous protease activity in the tested detergents retained up to 70% on incubation at 40 degrees C for 1 h, whereas less than 30% activity was only found on incubation at 50 degrees C for 1 h. The alkaline protease from an alkalophilic strain of Bacillus cereus was studied for its compatibility in commercial detergents. The cell free fermented broth from shake flask culture of the organism showed maximum activity at pH 10.5 and 50 degrees C. The protease from B. cereus showed much higher residual activity (more than 80%) on incubation with laundry detergents at 50 degrees C for 1 h or longer. The protease enzyme from B. cereus was found to be superior over the endogenous proteases present in the tested commercial laundry detergents in comparison to the enzyme stability during the washing at higher temperature, e.g., 40-50 degrees C.     

Calcium-induced folding and stabilization of the Pseudomonas aeruginosa alkaline protease

Pseudomonas aeruginosa is an opportunistic pathogen that contributes to the mortality of immunocompromised individuals and patients with cystic fibrosis. Pseudomonas infection presents clinical challenges due to its ability to form biofilms and modulate host-pathogen interactions through the secretion of virulence factors. The calcium-regulated alkaline protease (AP), a member of the repeats in toxin (RTX) family of proteins, is implicated in multiple modes of infection. A series of full-length and truncation mutants were purified for structural and functional studies to evaluate the role of Ca(2+) in AP folding and activation. We find that Ca(2+) binding induces RTX folding, which serves to chaperone the folding of the protease domain. Subsequent association of the RTX domain with an N-terminal α-helix stabilizes AP. These results provide a basis for the Ca(2+)-mediated regulation of AP and suggest mechanisms by which Ca(2+) regulates the RTX family of virulence factors.     

Bleach-stable, alkaline protease from Bacillus sp.

A bleach-stable, thermotolerant, alkaline protease for detergent formulation from a newly isolated Bacillus SB5 is reported. Most (85%) activity of the enzyme was retained in the presence of 10% (v/v) H2O2 and 1% SDS (w/v) at 40°C, after 1 h. The enzyme was optimal at pH 10 and 60°C to 70°C. Enzyme activity was enhanced 30 to 80% in presence of ionic and non-ionic detergents, surfactants and commercial detergents or bleach.     

Metabolic flux analyses for serine alkaline protease production

The intracellular metabolic fluxes through the central carbon pathways in Bacillus licheniformis in serine alkaline protease (SAP) production were calculated to predict the potential strategies for increasing the performance of the bacilli, by using two optimization approaches, i.e. the theoretical data-based (TDA) and the theoretical data-based capacity (TDC) analyses based on respectively minimum in-vivo SAP accumulation rate and maximum SAP synthesis rate assumptions, at low-, medium-, and high-oxygen transfer conditions. At all periods of low-oxygen transfer condition, in lag and early exponential periods of medium-oxygen transfer (MOT) condition, and SAP synthesis period of high-oxygen transfer (HOT) condition, the TDA and TDC analyses revealed that SAP overproduction capacity is almost equal to the observed SAP production due to the regulation effect of the oxygen transfer. In the growth and early SAP synthesis period and in SAP synthesis period at MOT condition the calculated results of the two analyses reveal that SAP synthesis rate of the microorganism can be increased 7.2 and 16.7 folds, respectively; whereas, in the growth and early SAP synthesis period at HOT condition it can be increased 12.6 folds. The diversions in the biochemical reaction network and the influence of the oxygen transfer on the performance of the bacilli were also presented. The results encourage the application of metabolic engineering for lifting the rate limitations and for improving the genetic regulations in order to increase the SAP production.