产耐高温纤维素酶细菌的筛选及酶学性质研究
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摘要
纤维素酶的研究对利用具有巨大潜力的可再生资源——纤维素有重要意义。实验筛选出了产耐高温纤维素酶的细菌菌株,获得了有良好耐热性的纤维素酶,并对筛得的菌株的生理生化特性及所产酶的酶学特性进行了研究。实验利用柴草进行高温堆肥,采样后用半限制性培养基筛选,筛选过程中,用3,5—二硝基水杨酸比色法测量所产纤维素酶活,并通过测不含菌体的发酵液酶活,来判断所产是否为胞外酶,结果筛得一株能产胞外耐高温纤维素酶的菌株。通过菌体观察实验、菌体运动性实验、V-P实验、甲基红实验、淀粉水解实验、过氧化氢酶生成测定实验、碳源利用实验等,对筛得的菌株进行分类鉴定,初步判定其属于嗜热脂肪芽孢杆菌(Bacillus stearothermophilus)。利用盐析、凝胶过滤层析等方法对纤维素酶进行分离纯化,用SDS-聚丙烯酰胺凝胶电泳检验,电泳结果中出现多条带,而Native—聚丙烯酰胺凝胶电泳结果只显示一条带,初步判定其为多亚基结构,至少有八个亚基。论文研究了该菌所产纤维素酶的最适温度、pH值、稳定性、酶活影响因子及Km值,确定其最适温度在60℃~70℃之间,最适pH值为7.0。用薄层层析的方法,将酶促反应产物与标准样进行比较,鉴定酶促反应产物,结果显示产物主要为葡萄糖。
A thermophil bacterial strain was isolated, in order to gain thermostable cellulase that can convert cellulose, the most abundant renewable source in the world, into glucose and soluble sugars. Physiological and biochemical characteristics of the strain and characteristics of the cellulase were studied. The diluted samples selected from hot compost were cultured on the hemi-restrictive culture medium. The cellulase activities of different strains were measured and compared by the method of DNS. Besides, the cellulase activity of the ferment liquid with bacterium and that of clear liquid without bacterium were compared to determine if the cellulase was extracellular. Physiological and biochemical characteristics of the strain were studied. The results of tests show that the target strain is Bacillus stearothermophilus. Cellulase was purified from ferment liquid by salt out and gel-filteration. The purified cellulase was resolved into at least 8 subunits by sodium dodecyl sulphate-polyacrylamide gel electropho
resis. But, PAGE without SDS didn't resolve it. The characteristics of the cellulase were studied. These characteristics include optimum temperature, optimum pH, and effect of various factors and the value of Km. The results show that the optimum temperature of cellulase reaction process rangs from 60℃~70℃ and the optimum pH is 7.0. The cellulase product and standard samples were compared by thin layer chromatography (TLC) to determine what the product was. The results show that the cellulase product is mainly glucose.
A thermophil bacterial strain was isolated, in order to gain thermostable cellulase that can convert cellulose, the most abundant renewable source in the world, into glucose and soluble sugars. Physiological and biochemical characteristics of the strain and characteristics of the cellulase were studied. The diluted samples selected from hot compost were cultured on the hemi-restrictive culture medium. The cellulase activities of different strains were measured and compared by the method of DNS. Besides, the cellulase activity of the ferment liquid with bacterium and that of clear liquid without bacterium were compared to determine if the cellulase was extracellular. Physiological and biochemical characteristics of the strain were studied. The results of tests show that the target strain is Bacillus stearothermophilus. Cellulase was purified from ferment liquid by salt out and gel-filteration. The purified cellulase was resolved into at least 8 subunits by sodium dodecyl sulphate-polyacrylamide gel electropho
resis. But, PAGE without SDS didn't resolve it. The characteristics of the cellulase were studied. These characteristics include optimum temperature, optimum pH, and effect of various factors and the value of Km. The results show that the optimum temperature of cellulase reaction process rangs from 60℃~70℃ and the optimum pH is 7.0. The cellulase product and standard samples were compared by thin layer chromatography (TLC) to determine what the product was. The results show that the cellulase product is mainly glucose.
引文
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[12] 傅博强,谢明勇,周鹏等.纤维素酶法提取茶多糖.无锡轻工大学学报,2002,21(4):362~366
[13] 梁靖,须海荣,蒋文莉等.纤维素酶在速溶茶中的应用研究.茶叶,2002,28(1):25~26
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[18] 余晓斌,施炜,全文海等.洗涤剂用碱性纤维素酶的研究(Ⅱ)——酶的提取
及性质.工业微生物,1998,28(2):10~14
[19] 冯群策.浅谈酶在非接触印刷废纸脱墨中的应用.黑龙江造纸,2002(4):18~20
[20] Vyas et al. Biodeinking of mixed office waste paper by alkaline active cellulases from alkalotolerant Fusarium sp.. Enzyme and Microbial Technology, 2003,32(2):236~245
[21] 颜家松,詹怀宇.造纸用酶活性的影响因素.生物技术,2001(6):62~64
[22] 王高升,谢来苏,隆言泉等.非接触印刷废纸酶促脱墨的研究.中国造纸,1999(4):10~15
[23] 宗娇娜,陈蕴智.新闻纸分类回用的方法及工艺.浙江造纸,2002(3):14~16
[24] 李宗全,于红,傅英娟等.纤维素酶木聚糖酶和淀粉酶用于混合办公废纸脱墨的研究.纤维素科学与技术,2002,10(2):1~7
[25] 张瑞萍.棉织物的生物酶煮练.南通工学院学报(自然科学版),2002,1(2):41~43
[26] A.Zadhoush.纤维素酶对涂层织物成品质量的影响,2002(5):16~18
[27] Jose Cegarra, The state of the art in textile biotechnology. Jannary of the Society of Dyers and Colourists, 1996,112(11):326~329
[28] 王海英,吴赞敏,景改玲等.纤维素酶处理与染色的研究.整染科技,2002(6):3~6
[29] 苏玉萍,林颖.酶在纺织行业的应用及发展前景.福建轻纺,1998(7):1~4
[30] 陈怡 译.最新的纺织酶.染整,1998(12):16~17
[31] 隋思清,李显波,李伟东.纯棉针织面料酶生物光洁整理工艺研究.山东纺织科技,1998(3):28~31
[32] 石军,李俊婷,田明雨.纤维素酶在畜牧业中的应用研究进展.饲料博览,2002(11):9~10
[33] 朱国生,李中利.添加纤维素酶制作玉米秸青贮料饲喂奶山羊的试验效果.饲料博览,2002(9):42
[34] 杨志刚,沈益新.纤维素酶制剂在青贮饲料中的应用.畜牧与兽医,2002.,34(9):37~40
[35] 潘锋.秸杆微生物共发酵生产单细胞蛋白研究:[博士论文],2001
[36] 马田田.纤维素酶用于中药提取的初步研究.中草药,1994,25(3):223
[37] 张鸿雁.微生物纤维素酶分子生物学研究进展.生物技术,2003,13(3):41~42
[38] 刘家建,路怡.纤维素酶的研究及应用综述.化工通讯,1995,1:6~10
[39] 刘春芬,贺稚非,蒲海燕等.纤维素酶及应用现状.粮食与油脂,2004,1:15~
17
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