碱性蛋白酶的发酵与酶学性质的研究
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摘要
本文对一株碱性蛋白酶高产菌株的发酵培养基及发酵条件进行了优化,并对酶的分离纯化工艺及酶的主要性质进行了研究。本文研究的主要内容和结论如下:
1、通过对菌株发酵培养基主要成分的逐个替代实验,实现了生产原料的国产化,并确定其培养基配方为:棉籽饼粉(80目)3%,酵母浸粉1.75%,麦芽糊精(DE≥30%)10%,柠檬酸钠0.3%,CaCl_2 0.3%,K_2HPO_4 1%。
2、对菌株的发酵条件进行了优化,确定了其最适摇瓶发酵条件:种龄12h,接种量2%,装液量50ml/250ml,摇床转速200r/min,培养温度34℃,发酵54h,碱性蛋白酶的发酵单位可达33985u/ml,达到进口原料的生产水平。在此基础上进行了7L发酵罐发酵工艺的优化,确定其工艺参数为:装料系数0.65,接种量5%,温度34℃,转速200~500r/min,通风量1:0.5~1:2.5,溶氧维持在30~40%。采用自动流加工艺,控制发酵液pH值不低于7.0,发酵50h。采用该工艺连续发酵三批,碱性蛋白酶产量稳定,平均为36471u/ml。
3、采用盐析及离子交换柱层析等方法对酶进行了纯化,SDS-PAGE表明纯化后的样品已达到电泳纯,分子量为28kDa。经过纯化,酶的比活力达18620.20u/mg,纯化了5.23倍,酶活力回收率为27.54%。
4、对酶的性质进行了研究。当以酪蛋白为底物时,其最适作用pH为10~11,最适作用温度为40~60℃。此外,该酶在pH7~12的范围内稳定,在45℃左右有较好的热稳定性。
The fermentation medium and the conditions of a high yield strain producing high alkaline protease were studied, the purification and the characterization of the alkaline protease were also studied. The main contents and the results of the study were as follows:
1. The main components of the medium were substituted one by one, and all of the producers' goods were homemade. The optimum medium were consist of: cotton seed meal 3%, yeast extract 1.75%, maltrin (DE 30%) 10%, Nacitrate 0.3%,CaCl20.3%, K2HPO4l%.
2. The optimum fermentation conditions were confirmed: seed age 12h, inoculum volume 2%, a 250ml flask containing 50ml medium, 200r/min, 34 C, and the highest enzyme activity was 33985u/ml after cultivated 54h. The experiment was also scaled up in the 7L fermentor. Controlling the fermented broth pH value over 7.0 by the feeding process, the alkaline protease activity was about 36579u/ml of the crude enzyme liquor.
3. The alkaline protease was purified using ammonium sulphate precipitation and ion exchange chromatography. The specific activity was 18620.20u/mg, 27.54% of the alkaline protease was recovered with 5.23-fold purification.
4. The optimum pH and temperature toward the hydrolysis of casein were pH 10-11 and 40~60 C. The alkaline protease was stable at pH 7~12 and about 80% of the initial enzymatic activity was retained after a 120min incubation period at pH 10.5 and 45 C.
1、通过对菌株发酵培养基主要成分的逐个替代实验,实现了生产原料的国产化,并确定其培养基配方为:棉籽饼粉(80目)3%,酵母浸粉1.75%,麦芽糊精(DE≥30%)10%,柠檬酸钠0.3%,CaCl_2 0.3%,K_2HPO_4 1%。
2、对菌株的发酵条件进行了优化,确定了其最适摇瓶发酵条件:种龄12h,接种量2%,装液量50ml/250ml,摇床转速200r/min,培养温度34℃,发酵54h,碱性蛋白酶的发酵单位可达33985u/ml,达到进口原料的生产水平。在此基础上进行了7L发酵罐发酵工艺的优化,确定其工艺参数为:装料系数0.65,接种量5%,温度34℃,转速200~500r/min,通风量1:0.5~1:2.5,溶氧维持在30~40%。采用自动流加工艺,控制发酵液pH值不低于7.0,发酵50h。采用该工艺连续发酵三批,碱性蛋白酶产量稳定,平均为36471u/ml。
3、采用盐析及离子交换柱层析等方法对酶进行了纯化,SDS-PAGE表明纯化后的样品已达到电泳纯,分子量为28kDa。经过纯化,酶的比活力达18620.20u/mg,纯化了5.23倍,酶活力回收率为27.54%。
4、对酶的性质进行了研究。当以酪蛋白为底物时,其最适作用pH为10~11,最适作用温度为40~60℃。此外,该酶在pH7~12的范围内稳定,在45℃左右有较好的热稳定性。
The fermentation medium and the conditions of a high yield strain producing high alkaline protease were studied, the purification and the characterization of the alkaline protease were also studied. The main contents and the results of the study were as follows:
1. The main components of the medium were substituted one by one, and all of the producers' goods were homemade. The optimum medium were consist of: cotton seed meal 3%, yeast extract 1.75%, maltrin (DE 30%) 10%, Nacitrate 0.3%,CaCl20.3%, K2HPO4l%.
2. The optimum fermentation conditions were confirmed: seed age 12h, inoculum volume 2%, a 250ml flask containing 50ml medium, 200r/min, 34 C, and the highest enzyme activity was 33985u/ml after cultivated 54h. The experiment was also scaled up in the 7L fermentor. Controlling the fermented broth pH value over 7.0 by the feeding process, the alkaline protease activity was about 36579u/ml of the crude enzyme liquor.
3. The alkaline protease was purified using ammonium sulphate precipitation and ion exchange chromatography. The specific activity was 18620.20u/mg, 27.54% of the alkaline protease was recovered with 5.23-fold purification.
4. The optimum pH and temperature toward the hydrolysis of casein were pH 10-11 and 40~60 C. The alkaline protease was stable at pH 7~12 and about 80% of the initial enzymatic activity was retained after a 120min incubation period at pH 10.5 and 45 C.
引文
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[3] 方海红,胡好远,黄红英等.微生物碱性蛋白酶的研究进展[J],微生物学通报,2002,29(2):57~59。
[4] Keay L, in: Ferment. Technology Today[M], Gyozo Terui ed. Society of Fermentation Technology, Japan, 1972, 289~298
[5] Fastrez J, Fersht. Demonstration of the acyl-enzyme mechanism for the hydrolysis of peptides and anilides by chymotrypsin[J]. Biochemistry. 1973, 12:2025~2034
[6] Maurizi MR, Trisler P, Isono M et al. A new proteolytic enzyme from Achromobacter lyticus M497-1 [J]. Agric. Bio. Chem. 1978, 42:1443~1445
[7] Yoshimoto T, Walter R, Tsuru D. Proline-specific endopeptidase from Flavobacterium: purification and properties[J]. J. Biol. Chem. 1980, 225: 4786~4792
[8] Drapeau GR, Boily Y, Houmard J. Purification and properties of an extracelluar protease of Staphylococcus aureus[J]. J. Biol. Chem. 1972, 247: 6720~6726
[9] Barett A J. Proteolytic enzymes: serine and cysteine peptidases[J]. Methods Enzymol. 1994, 244:1~15
[10] Brenner S. The molecular evolution of genes and proteins: a tale of two serines[J]. Nature. 1988, 334:528~530
[11] Jany K D, Lederer G, Mayer B. Amino acid sequence of protease catalysis based on the mold Tritirachium album Limber[J]. FEBS Lett. 1986, 199: 139~144
[12] Austew B M, Smith E L. Action of staphylococcal proteinase on peptides of varying chain length and composition[J]. Biochem. Biophys. Res. Commun. 1976, 72:411~417
[13] Calik P, Takac S, Calik G et al. Serine alkaline protease overproduction capacity of Bacillus licheniformis[J]. 2000, 26:45~46
[14] 王伟民,曹裕华,王宜敏等.连续处理法选育地衣芽孢杆菌碱性蛋白酶菌株[J],工业微生物,1993,23(5):1~4
[15] 那淑敏,余茂效.一株产碱性蛋白酶菌株的选育及其发酵条件的研究[J],微生物学报,1988,28(3):249~256
[16] Larst and Cove. Methylammonium resistance in Aspergillus nidulans[J]. J. Bacteriol, 1969, 98: 1284~1294
[17] Munro R E. [J] Biochemical Journal, 1961,81: 225
[18] Spudich J A, Kornberg A J. [J] Journal of Biological Chemistry, 1968, 243: 4600
[19] 中华人民共和国行业标准:工业酶制剂通用试验方法,QB/T 1803—93,1994
[20] 那淑敏,余茂效.一株碱性蛋白酶地衣芽孢杆菌的选育[J],微生物学报,1988,15:101-104
[21] 邱秀宝,袁影,戴宏等.嗜热脂肪芽孢菌碱性蛋白酶的研究[J],微生物学报,1990,30:129-133
[22] 徐子渊,朱青虹,王建华.碱性蛋白酶产生菌C1213的选育[J],食品与发酵工业,1984,4:12~16
[23] 郑铁曾,涂提坤,黄登禹等.提高C1213菌碱性蛋白酶活力的研究[J],食品与发酵工业,1993,1:25-31
[24] 诸葛健,周历萍,王萍等.蛋白酶生产菌种间原生质体融合的研究[J],微生物学报,1984,24.74-79
[25] 冯清平,沈剑敏,高燕.嗜碱性地衣芽孢杆菌53-A_6的选育[J],兰州大学学报(自然科学版),1993,32:83-87
[26] 徐威,龚淑娟,孙平平.利用原生质体诱变筛选碱性蛋白酶高产菌株[J],微生物学杂志,1996,16(3):18
[27] 徐威,龚淑娟,孙平平.紫外线诱变选育碱性蛋白酶高产菌株[J],微生物学杂志,1997,17(12):23
[28] 江盛梅,沈萍.嗜麦芽假单胞菌的碱性蛋白酶基因在大肠杆菌中的克隆与表达[J],生物工程学报,1993,9(3):266-270
[29] 雷虹,洪杨,张玉瑛,申同健.地衣芽孢杆菌2709碱性蛋白酶编码序列的PCR扩增、克隆及序列测定[J],生物化学杂志,1993,9(4):441-447
[30] 刘永亮,童克忠.利用枯草杆菌碱性蛋白酶E基因的信号顺序构建分泌表达载体[J],遗传学报,1994,21(3):235-246
[31] 赵云德,王贤舜,郑屹.地衣芽孢杆菌2709碱性蛋白酶基因的克隆与序列分析[J],生物化学与生物物理学报,1993,25(6):577-583
[32] 王培之,王贤舜.用遗传工程的方法构建一个分泌型高表达的枯草杆菌碱性蛋白酶表达系统[J],生物化学杂志,1993,9(2):208-212
[33] 杨文博,冯耀宇.利用淀粉产生碱性蛋白酶工程菌的构建[J],微生物学通报,1994,21(5):273-278
[34] 唐雪明,王正祥,邵蔚蓝.碱性蛋白酶工程菌发酵条件及重组酶的纯化和
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