纤维素酶浓度在确定微晶纤维素水解中协同作用程度方面的作用。

The role of cellulase concentration in determining the degree of synergism in the hydrolysis of microcrystalline cellulose.

作者信息

Woodward J, Lima M, Lee N E

机构信息

Chemical Technology Division, Oak Ridge National Laboratory, TN 37831-6194.

出版信息

Biochem J. 1988 Nov 1;255(3):895-9. doi: 10.1042/bj2550895.

DOI:10.1042/bj2550895

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1135325/

Abstract

Microcrystalline cellulose (10 mg of Avicel/ml) was hydrolysed to glucose by different concentrations of the purified cellulase components endoglucanase (EG) II and cellobiohydrolases (CBH) I and II, alone and in combination with each other, in the presence of excess beta-glucosidase. At a concentration of 360 micrograms/ml (160 micrograms of EG II/ml, 100 micrograms of CBH I/ml and 100 micrograms of CBH II/ml) the degree of synergism among them was negligible. As the concentration of cellulase decreased, the degree of synergism increased, reaching an optimum at 20 micrograms/ml (5 micrograms of EG II/ml, 10 micrograms of CBH I/ml and 5 micrograms of CBH II/ml). There was no apparent relationship between the ratio of the components and the degree of synergism. The latter is probably due, though it could not be proved, to the level of saturation of the substrate with each component. Inhibition of Avicel hydrolysis was observed when the substrate was incubated with saturating and nonsaturating concentrations of a mixture of EG II and CBH I respectively. A similar result was also observed with a combination of EG I and EG II.

摘要

在过量β-葡萄糖苷酶存在的情况下，微晶纤维素（10毫克微晶纤维素/毫升）被不同浓度的纯化纤维素酶组分内切葡聚糖酶（EG）II、纤维二糖水解酶（CBH）I和CBH II单独或相互组合水解为葡萄糖。在浓度为360微克/毫升（160微克EG II/毫升、100微克CBH I/毫升和100微克CBH II/毫升）时，它们之间的协同程度可忽略不计。随着纤维素酶浓度的降低，协同程度增加，在20微克/毫升（5微克EG II/毫升、10微克CBH I/毫升和5微克CBH II/毫升）时达到最佳。各组分的比例与协同程度之间没有明显关系。尽管无法证实，但协同程度可能是由于底物与各组分的饱和水平所致。当底物分别与饱和浓度和非饱和浓度的EG II和CBH I混合物孵育时，观察到微晶纤维素水解受到抑制。用EG I和EG II的组合也观察到了类似的结果。

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